Climate justice and the built environment


EDITORIAL

Climate justice and the built environment
Sonja Klinsky1 and Anna Mavrogianni2

Highlights
Climate justice is explained and explored in relation to how decisions about the built environment 
in the climate context intersect with human wellbeing. Key features in the built environment are 
identified that impact upon climate injustice. Specific processes, decisions and actions are identified 
to reduce these injustices and to reduce current gaps both in knowledge and practices. A conceptual 
and practical context is provided for integrating concerns about climate justice into research and 
decision-making about the built environment by addressing four underlying questions: 1. What 
is climate justice and why is it a significant issue? 2. Why is the built environment important 
in addressing climate injustice, and why is climate justice essential for the built environment 
community to consider? 3. What processes can be used to reduce inequities and injustices in the built 
environment? 4. What roles might the academic community, governmental entities, and practitioners 
in construction, design and real estate, have in facilitating deeper integration of climate justice? 
A capabilities approach is proposed to systematically uncover and address underlying patterns of 
injustice. A multi-valent approach involving distributive, procedural and recognition justice can 
be harnessed to constitute a justice framework. A process of change is needed to: (i) reframe, 
reposition and extend current built environment research to engage with wider issues of justice, 
(ii) build and make accessible the evidence base for the identification and mitigation of inequities 
in climate risk exposures, vulnerabilities, and effective and equitable adaptation pathways and (iii) 
define responsibilities for different actors.

Keywords: adaptation; built environment; cities; climate justice; equity; human development; poverty; 
resilience; social justice; vulnerability

Klinsky, S., & Mavrogianni, A. (2020). Climate justice and the built 
environment. Buildings and Cities, 1(1), pp. 412–428. DOI: https://
doi.org/10.5334/bc.65

1. Introduction
It is widely acknowledged that questions of justice are embedded in every aspect of climate change, and that ongoing 
and future anthropogenic climate change will exacerbate inequities worldwide. Cumulative global emissions have 
been dominated by processes of industrialisation from the Global North, leaving limited atmospheric space for similar 
processes in the Global South if atmospheric concentrations are to be kept below levels that would lead to a 1.5 or 
2°C change in global average temperature. Simultaneously, global climate change impacts including sea level rise and 
increases in the frequency and severity of extreme weather events are also uneven across and within countries (IPCC 
2018). Both extreme events and slow onset impacts can harm infrastructure, present significant financial challenges to 
communities, and generate a myriad of health and wellbeing implications. Such health impacts can include immediate 
threats to life, changes in long-term conditions including asthma and heat-related stress, challenges to mental health, 
and shifts in disease vectors (Watts et al. 2019). Climate change will also function as a ‘risk modifier’ in the built 
environment, exacerbating inequalities and inequities associated with indoor environmental exposures, such as excess 
indoor temperatures, indoor air pollution, contaminated water, allergens and mould (Vardoulakis et al. 2015).

This special issue presents climate justice studies by seven groups of researchers. The papers, which were selected from 
36 submitted abstracts, describe work conducted in Australia, Germany, Kenya, Poland, the UK and the US (Table 1). 
They describe a range of approaches for understanding the manifestations of climate injustice in the context of the 
built environment and identify specific processes, decisions and actions that can be taken to reduce these injustices. 

1 Arizona State University, School of Sustainability, Tempe, AZ, US. ORCID: 0000-0002-9450-1249
2 University College London, Bartlett Faculty of the Built Environment, Institute for Environmental Design and Engineering, London, 
UK. ORCID: 0000-0002-5104-1238

Corresponding author: Anna Mavrogianni (a.mavrogianni@ucl.ac.uk)

https://doi.org/10.5334/bc.65
https://doi.org/10.5334/bc.65
https://orcid.org/0000-0002-9450-1249
https://orcid.org/0000-0002-5104-1238
mailto:a.mavrogianni@ucl.ac.uk


Klinsky and Mavrogianni 413

Despite this breadth, the special issue also reveals some gaps both in our knowledge and practices. Accordingly, it 
aims to initiate a process of change and discussion that will ultimately break disciplinary silos in order to: (1) reframe, 
reposition and extend current built environment research to engage with wider issues of justice; and (2) build the 
evidence base for the identification and mitigation of inequities in climate risk exposures, vulnerabilities, and effective 
and equitable adaptation pathways.

This editorial places these papers in context and provides a starting point for more fully integrating concerns about 
climate justice into research and decision-making about the built environment. It was motivated by considering four 
underlying questions of direct relevance to those in the built environment community:

•	 What is climate justice and why is it a significant issue?
•	 Why is the built environment important in addressing climate injustice, and why might climate justice be essential 

for the built environment community to consider?
•	 What processes can be used to reduce inequities and injustices in the built environment?
•	 What roles might the academic community, governmental entities, and practitioners in construction, design and 

real estate, have in facilitating deeper integration of climate justice into work on the built environment?

Building from these underlying questions, this editorial considers the major dimensions of climate justice, and 
maps some of the ways in which decisions about the built environment in the climate context intersect with human 
wellbeing. Using a capabilities lens (Sen 1999, 2005) combined with a multivalent approach to justice, it then proposes 
a framework to help those in the built environment community more systemically locate their work within the scope 
of considerations about justice in the climate context. The end of this editorial issues key challenges for the academic 
community, construction and real estate sectors, governments and communities.

2. Dimensions of climate injustice
The central claims of climate injustice involve four key interconnected dimensions. The first is that there are vast 
disparities in causal responsibility for greenhouse gas (GHG) emissions that have cumulative driven climate change. 
The US alone is responsible for 26% of all cumulative emissions since the industrial revolution, and the EU is similarly 
responsible for 23%. Meanwhile, despite having much larger populations, India’s total cumulative emissions are only 
about 3% of the global total, while even China is responsible for only 12% (Gütschow et al. 2016). These disparities 
become even more stark when considered on a per capita basis. Cumulative emissions are particularly relevant from a 
built environment perspective because these accumulated emissions result from the creation and use of hospitals and 
roads, railways, housing, schools, factories, office towers, etc. While emissions themselves are invisible, the benefits they 
have yielded are distinctly embodied in daily life, have accumulated unevenly, and cannot be ignored in any discussion 
about the built environment and climate justice. Historical responsibility for climate change has been a central part of 

Table 1: Articles in this special issue ‘Climate Justice: The Role of the Built Environment’, Buildings and Cities (2020), 
1(1); guest editors Anna Mavrogianni and Sonja Klinsky.

Authors Title DOI

S. Klinsky & A. Mavrogianni Climate justice and the built environment 10.5334/bc.65

M. Baborska-Narozny, M. Szulgowska, M. 
Mokrecka, A. Chmielewska, N. Fidorow-Kaprawy, 
E. Stefanowicz, K. Piechurski & M. Laska

Climate justice: air quality and transitions from 
solid fuel heating

10.5334/bc.23

N. Willand, T. Moore, R. Horne & S. Robertson Retrofit poverty: socioeconomic spatial disparities 
in retrofit subsidies uptake

10.5334/bc.13

C. Schünemann, A. Olfert, D. Schiela, K. Gruhler, 
& R. Ortlepp

Mitigation and adaptation in multifamily housing: 
overheating and climate justice 

10.5334/bc.12

Z. Hamstead, P. Coseo, S. AlKhaled, E. F. Boamah, D. 
M. Hondula, A. Middel, & N. Rajkovich

Thermally resilient communities: creating a 
socio-technical collaborative response to extreme 
temperatures

10.5334/bc.15

M. Patrick, G. Grewal, W. Chelagat & G. Shannon Planetary health justice: feminist approaches to 
building in rural Kenya

10.5334/bc.18

S. Axon & J. Morrissey Just community transitions? Social inequity, 
vulnerability, and unintended consequences

10.5334/bc.14

U. Passe, M. C. Dorneich, C. Krejci, D. Malekpour, 
B. Marmur, L. Shenk, J. Stonewall, J. Thompson 
& Y. Zhou

Urban modelling framework for climate 
resilient energy use decisions in low-resource 
neighbourhoods

10.5334/bc.17

https://doi.org/10.5334/bc.65
https://doi.org/10.5334/bc.23
https://doi.org/10.5334/bc.13
https://doi.org/10.5334/bc.12
https://doi.org/10.5334/bc.15
https://doi.org/10.5334/bc.18
https://doi.org/10.5334/bc.14
https://doi.org/10.5334/bc.17


Climate justice and the built environment414

all debates about climate justice (Agarwal & Narain 1991; BASIC Expert 2011; LaRovere, Valente de Macedo, & Baumert 
2002) and is unavoidable, especially in light of its intersection with other dimensions of climate injustice.

The second and third dimensions of climate injustice are inextricably entwined: (1) climate impacts are unevenly 
distributed as is (2) vulnerability to these impacts due to pre-existing patterns of privilege and marginalisation (Field et 
al. 2014; Tschakert et al. 2013). Low income, socially and economically marginalised communities, individuals suffering 
from chronic diseases or social isolation, older and young people, and vulnerable populations will be disproportionately 
affected by climate change due to their limited ability to adapt (Baker 2012), and these variables operate within 
domestic and international spheres. Many of those with least resources will face the most intense climate impacts, and 
insufficient climate action will negatively affect the achievement of the United Nations’ (UN) Sustainable Development 
Goals (SDG) promoting the wellbeing of people in developing countries and low income and marginalised communities 
within wealthy countries (UN 2015). For instance, when Hurricane Katrina (2005) hit New Orleans 1200 people died. 
The highest proportion of victims were people aged 65 and over; African Americans were significantly over-represented 
amongst the victims across all age categories (Sharkey 2007). Moreover, African Americans were less likely to have 
returned to New Orleans as they had proportionally experienced more intense housing losses (Fussell, Sastry, & 
VanLandingham 2010), a permanent migration which represents profound and uneven loss. The depth of inequality 
from extreme events is intensified even further in countries with fewer resources. A relatively comparable storm with 
Hurricane Katrina in the Philippines, Typhoon Haiyan (2013), left at least 6300 dead. Six years afterwards, socioeconomic 
inequalities amongst survivors continued to shape the nature of recovery (Madianou 2015).

The asymmetry of inequities in vulnerability between and within societies is a particularly sharp form of injustice. 
Many of those who are most vulnerable have contributed least to climate change and many of the processes fuelling 
systemic inequalities are tied to the accumulation of wealth and privilege that resulted in climate change in the first 
place (Cameron 2012; Haines et al. 2007: 200; Islam & Winkel 2017). Industrialisation and infrastructure development 
of parts of the world has been supported through exploitation in others. For instance, fossil fuel development in its 
current form across North America would not be possible without the expropriation of Indigenous territories through 
settler colonialism (Whyte 2020). The relationships between industrialisation, colonialism, slavery and global capital 
accumulation (Malm 2013) are not neatly linear but they are deeply entwined. Acknowledging these connections 
may be essential for designing strategies capable of moving towards more just arrangements at a fundamental level. 
These interconnections have long been articulated by climate justice activists (CJN! 2004; ICJN 2002) but remain only 
tentatively recognised in broader scholarship, although this is changing as people come to more deeply interrogate the 
causes and potential strategies for ameliorating climate injustice (Cameron 2012; Grear 2014; Saad 2017; Whyte 2020).

The fourth justice dimension is that temporal, social and spatial distance separates the causes and effects of climate 
change. Those who have benefited from emissions and those who are most harmed are segregated from each other 
by social or physical distance and time. This generates new problems for decision-making and accountability. People 
outside of a given jurisdictional boundary, those inside a boundary but who are not recognised (i.e. those without 
documentation or citizenship, or those experiencing systemic discrimination), or those who are not yet born may 
be excluded by decision-making representatives and analysts as they are not held directly accountable to them. The 
widespread exclusion of those who are most vulnerable within jurisdiction-specific decisions almost by definition 
presents profound challenges for procedural justice. How should future people or those who reside outside of any 
particular jurisdictional boundary—neighbourhood, city, country, region—be recognised or represented in decision-
making? There is good reason that philosopher Stephen Gardiner has long since identified climate change as a ‘perfect 
moral storm’ (Gardiner 2006).

Actors in any given system have specific rights and responsibilities, and some may hold moral claims against others 
for failing to uphold their responsibilities. While observations of inequities are important, a focus on justice opens up 
consideration of both the underlying processes by which inequities are generated and the responsibilities different 
actors have within this. A climate justice approach can provide an analysis which is actionable based on understanding 
whose rights and responsibilities are at play in any given situation and how they are related. Examples of this might 
include not only identifying why particular people are unusually vulnerable to a specific climate impact, but who has 
specific responsibilities to address these vulnerabilities. Such responsibilities can be based on some causal connection 
through climate change or some other pre-existing relationship (such as systemic discrimination) or because of roles 
which come with specific obligations, such as a government’s obligation to provide essential services, or a contractor’s 
obligation to ensure the long-term safety of a building. In the built environment context, key actors with responsibilities 
might include individual people or categories of people, such as residents and clients, designers, service providers, 
contractors and builders, along with decision-makers representing all levels of collective organisations, such as local to 
national governments, corporations, and civil society organisations.

3. The built environment and climate injustice
Due to the pace of climate change and the urgency of efforts to avert it, interrogation of the intersection between 
justice, the built environment and climate change is a timely arena of enquiry. The built environment is where most 
people work, live and play; it is literally built into the fabric of society and will be central to both climate mitigation 
and adaptation to climate impacts. From a mitigation perspective, the built environment is a significant contributor 



Klinsky and Mavrogianni 415

of GHG emissions globally, which makes it a key sector to include in any mitigation efforts. As of 2016, residential and 
commercial buildings accounted for 17.5% of GHG emissions globally (WRI 2020). From an adaptation perspective, 
many climate impacts occur at the level of cities, neighbourhoods or individual buildings, making the built environment 
a central locus for adaptation planning and decision-making. In both contexts, three key features underpin the inherent 
relationship between climate injustice and the built environment; (1) long time-frames involved; (2) the embedded 
accumulation of privilege and disadvantage within the built environment; and (3) the tight synergies between broader 
health and societal benefits with climate-friendly approaches to the built environment. Each is briefly considered below.

3.1. Long timeframes
Decisions about the built environment are particularly important in the climate context due to the longevity and path 
dependency of the building stock and infrastructure. Built infrastructure lasts for a long time: any decision taken now 
will continue to shape surrounding decisions for many years—50, 100 or more. The diversity in building stock turnover 
rates needs to be considered as part of any climate change adaptation or mitigation pathway. Whilst the building stocks 
of ‘mature’ economies are characterised by slow demolition and replacement rates (Power 2008), those of growing 
economies (e.g. India, China, Africa) have much shorter building life expectancies and will be building rapidly over 
the next 10–20 years. By way of illustration, the average building lifespan in China is estimated to be 25–35 years as 
opposed to 70–175 years across European countries (Marsh 2017; Sandberg et al. 2016; Wang, Zhang, & Wang 2018). In 
addition, decisions about the types of housing, industrial centres or neighbourhood design result in commitments to 
particular forms of energy and ways of life that are difficult to shift and, thus, result in a diversity of social, economic, 
energy, resources, and physical path dependencies. Taking a climate justice approach to questions about the built 
environment can inform efforts to avoid maladaptive responses to climate change and lock-in measures that will play 
out for a longer period of time, and to promote decision-making that seeks to move towards a more just society in 
which all can flourish (Kelman 2020).

3.2. Embedded accumulation
The interaction between climate change and pre-existing patterns of cumulative privilege and disadvantage that have 
been embedded in the built environment raise questions about the extent to which adaptation or mitigation decisions 
will reduce or increase the inequalities already being experienced across societies. A growing body of literature has been 
highlighting the urgent need to broaden the focus from the ‘vulnerable’ in society to include critical reflection about 
systemic inequalities and structural vulnerabilities (Tschakert et al. 2013). This is particularly important for the built 
environment sector where decision-making processes are multilayered, interconnected and complex. A wide range of 
different actors is usually involved (national, regional and local governments, clients, designers and contractors, service 
providers, communities), often with conflicting agendas and priorities. The potential for pre-existing inequities to 
deepen climate impacts in all countries is increasingly well documented across a wide range of dimensions immediately 
related to the built environment including heat stress (Byrne et al. 2016); access to public open space and shade coverage 
(Mitchell & Chakraborty 2015; Kolosna & Spurlock 2019; Smith & Henríquez 2019; Wilson & Chakraborty 2013); and 
access to essential services (Gibson 2019; Hale 2019), to name a few.

3.3. Wellbeing and built environment synergies
The creation of sustainable local communities, low-carbon buildings and active transport are expected to have wider 
health and social benefits. As stated in the Marmot Review (Marmot et al. 2010), social inequalities in health should be 
tackled alongside climate change, and these two aims are ‘entirely compatible’. A series of Lancet papers published in 
2009 (Friel et al. 2009; Markandya et al. 2009; Smith et al. 2009; Wilkinson et al. 2009; Woodcock et al. 2009) explored 
the potential for climate change mitigation policies to result in public health improvements, thus strengthening the 
case for the socioeconomic benefits of climate change mitigation policy (Deng et al. 2017; Gao et al. 2018; Haines et al. 
2009; Milner et al. 2020; Vardoulakis et al. 2015). Similarly, public health-focused climate change adaptation strategies 
at the urban level, such as urban shading, and spaces that encourage physical activity and social connection, have been 
shown to have appreciable co-benefits, such as improvements in social capital, mental health improvements, reduced 
obesity and cardiovascular disease (Cheng & Berry 2013).

Many have argued that there are important synergies between the previously disconnected targets of climate change 
driven policies in the built environment sector and energy poverty reduction, and that these should be more strongly 
linked in both research and policy (Tozer 2020; Ürge-Vorsatz & Tirado Herrero 2012). There is a significant body of 
evidence demonstrating that, if developed and implemented appropriately, GHG emissions reduction strategies in 
the building stock have the potential to reduce underlying social and health inequalities, and help eradicate poverty. 
Energy efficiency improvements in low income housing, such as thermal insulation, has been found to improve 
indoor thermal conditions, perceived health and sense of wellbeing, and doctor/hospital appointments for respiratory 
conditions (Howden-Chapman et al. 2007). Although high energy efficiency standards, such as Passivhaus, may be 
routinely dismissed as non-affordable, recent research has demonstrated the potential to reduce construction costs 
through multi-objective optimisation, thus increasing their feasibility as a social housing option that could help reduce 
fuel poverty (Forde et al. 2020). However, it has been emphasised that, for climate change mitigation policies to avoid 



Climate justice and the built environment416

unintended consequences in relation to existing inequalities, a ‘pro-poor’ approach needs to be adopted (Markkanen & 
Anger-Kraavi 2019).

An example of a programme that has placed systemically marginalised communities at the centre of its planning 
in order to purposefully reap synergistic benefits from climate action is the Portland Clean Energy and Community 
Benefits Fund (PCEF). Community led and governed through a social norm of consensus and frontline leadership, this 
initiative addressed immediate community needs through a broader climate justice lens that included the creation of a 
consistent and long-term funding source for renewable energy, energy efficiency, green infrastructure and jobs training 
projects (Mondainé & Lee 2020).

Despite these potential synergies, several concerns about injustice stemming from both mitigation and adaption have 
emerged. For instance, in the mitigation context, although retrofitting is clearly an important element of increasing 
energy efficiency and alleviating fuel poverty, the potential for retrofit access opportunities and associated benefits are 
unevenly distributed due to differences in income and wealth or to the landlord–tenant relationship (Camprubí et al. 
2016; Gillard, Snell, & Bevan 2017; Schaffrin 2013; Teli et al. 2016). Similarly, winter energy poverty and climate policies 
may have regressive implications for low income households (Mallaburn & Eyre 2014). As global temperatures increase 
and overheating risk becomes an increasing concern, several authors have also highlighted the need to identify and 
quantify summer fuel poverty in temperate climates (Escandón, Suárez, & Sendra 2019; Sánchez-Guevara Sánchez et al. 
2017; Tabata & Tsai 2020; Thomson et al. 2019). Vulnerable households are often likely to live in a dwelling prone to 
overheating located within urban heat islands with poor green and blue infrastructure, and have limited cooling means, 
e.g. limited ventilation due to outdoor air pollution, noise, unsafe conditions or poor building design (Romero Lankao 
& Qin 2011). Heat events and air pollution disproportionately affect disadvantaged groups on the basis of income, age, 
ethnicity and marital status (Willers et al. 2016). The potential for greening efforts—including increasing green space 
and updating building energy efficiency—to drive gentrification and displacement of low-income households is another 
theme that has increasingly been recognised within this nexus (Cole et al. 2017; Wolch, Byrne, & Newell 2014).

Justice concerns have also emerged from discussion about climate adaptation in the context of the built environment. 
The most pressing of these has been exclusionary adaptation, e.g. adaptation planning that excludes informal settlements 
or communities with limited political power (Henrique & Tschakert 2019). Similarly, interest in green infrastructure 
both as a mitigation and adaption measure has been attended by concerns that the benefits may serve only some 
populations and, such as gentrification, result in the displacement of vulnerable people (Anguelovski, Irazábal-Zurita, 
& Connolly 2019; Turan 2018).

This special issue recognises the twin potentials that the built environment holds: the built environment can intensify 
injustices but also potentially address them in the climate context.

This editorial combines the capabilities approach with a multivalent focus on justice in order to develop a framework 
that could be used by researchers, practitioners and decision-makers to identify both potential climate justice concerns 
that emerge in the context of the built environment and actionable points of intervention that could help move towards 
more just arrangements.

4. A capabilities approach
Identifying systemic justice concerns and finding intervention points can be challenging. An abstract level of claims 
about justice may miss concrete opportunities for change. But focusing solely on concrete details can also flatten the 
analysis and fail to uncover underlying patterns. One of the benefits of focusing on the built environment from a 
climate justice approach is the centrality of this sector to core concerns of human safety, mobility and basic wellbeing.

Concern with human flourishing is at the heart of all the dimensions of climate justice identified above. The notion 
of capabilities provides a useful starting point for making the implications of climate justice claims more visible in 
actual decision-contexts. The capabilities approach starts with the recognition that human flourishing requires the 
ability to access and benefit from a range of opportunities and resources. While the exact manifestation of capabilities 
may vary and has been the subject of some debate (Nussbaum 2011; Sen 1999), a capabilities approach can be useful 
for identifying how concrete decisions about the built environment in the context of climate change could enhance 
or threaten human wellbeing. The Human Development Index (HDI) is one rough metric built on this notion and can 
be helpful at identifying broad trends, but focusing more in-depth on specific capabilities may have some benefits, 
particularly from the perspective of individuals and decision-makers having to make decisions. Table 2 provides a few 
examples of how mitigation and adaptation strategies in the context of the built environment interact with commonly 
cited capabilities. Each strategy contains both opportunities and challenges for justice. For instance, while a positive 
adaptation strategy might include proactive decisions about how to protect residential areas from extreme events 
or long-term climate impacts, the failure to do this, or to do this for some and not others, or possibly why some 
communities are vulnerable in the first place while others are not, raise concerns about injustice.

Table 2 makes clear the built environment can enable or inhibit capabilities for people to flourish. If investigated 
through a justice lens, deeper levels of the challenge are revealed. What capabilities have some secured access to 
through use of atmospheric space—manifest as things such as access to schools, hospitals, transportation systems, 
office buildings and safe homes—that have been denied to others? How does differential experience of benefits and 
burdens occur? Which capabilities, and for whom, are put at risk through particular climate impacts? How do climate 



Klinsky and Mavrogianni 417

Table 2: Examples of the interactions between climate change mitigation and adaptation strategies in the built 
environment and human flourishing capabilities.

Built environment support 
for capabilities

Climate change mitigation strategies Climate change adaptation strategies

Health: ‘A state of complete physical, mental and social wellbeing and not merely the absence of disease or infirmity’ 
(WHO 1948)

The capability of health in the built environment context includes not only the provision of adequate protection from harmful 
pollutants, thermal extremes, noise and safety hazards, both indoors and outdoors, but also the provision of services that allow 
people to accomplish their desired tasks safely and efficiently without physical or mental distress, and to promote physical and 
mental health and wellbeing (IWBI 2016; Perdue, Stone, & Gostin 2003). Recognising the inextricable link between human health 
and a healthy environment, ensuring people enjoy health, includes all large-scale environmental protections from the regional to 
the urban to the building scale

Outdoor environmental quality 
at multiple scales (global to 
neighbourhood): including control 
of greenhouse gas emissions, all 
pollutants of air, water and land 

Minimise environmental costs (proximate 
and distal) of all infrastructure

Protect proximate and distal landscapes 
and built environment from climate change 
impacts (e.g. heatwaves, droughts, floods, 
storms etc.) without intensifying climate 
change, reduce sources of outdoor air 
pollution through appropriate policies

Indoor environmental quality 
including air, sound and light 
quality, physical integrity

Ensure low-carbon building does not 
compromise indoor environmental quality

Enhance access to spaces of high indoor 
environmental quality; ensure efforts 
to enhance indoor environmental 
quality do not impose stress on 
outdoor environmental quality (proximate 
and distal)

Outdoor thermal adequacy Seek to reduce outdoor thermal stress 
imposed through the built environment, 
including microclimatic characteristics

Protect or enhance mechanisms for low-
carbon outdoor thermal comfort

Indoor thermal adequacy Recognise potential implications of 
mitigation policy on indoor thermal 
adequacy

Enhance access to domestic low-carbon 
thermal comfort control; ensure efforts to 
enhance indoor thermal comfort do not 
negatively affect outdoor thermal comfort 
and/or generate additional greenhouse gas 
emissions

Physical safety: Capability to live, work and participate in public life safely

This includes not only the existence but also the affordability of access to physically safe spaces for living, working and public life 
for all

Home Building and operation practices that 
provide high-quality, low-carbon, affordable 
housing

Minimise vulnerability of permanent and 
temporary residential areas to extreme 
climate events and long-term impacts

Care settings (e.g. care homes and 
extra-care homes)

Building and operation practices that 
provide high-quality, low-carbon care 
provision 

Minimise vulnerability of care settings 
to extreme climate events and long-term 
impacts

Work/school/public life Building and operation practices 
that provide high-quality, low-carbon 
infrastructure for employment, education 
and public life

Minimise vulnerability of workplaces, 
schools and public institutions to extreme 
climate events and long-term impacts

Accessibility and mobility Implementing low-carbon, safe and 
accessible mobility services; reduce non-
human-powered mobility needs overall

Ensure low-carbon transportation 
infrastructure, including human-powered 
mobility systems, is accessible and designed 
to function through extreme climate events 
and long-term impacts

Cultural vitality: Capability to sustain a thriving cultural life

Cultural vitality requires attention to both the experience of individuals and the potential for collective experiences to be nurtured

Public spaces Building high-quality, low-carbon public 
spaces (including protecting adequate 
green space) designed to nurture public and 
cultural life

Ensure protections and inclusive access for 
public space in order to meet the diversity 
of needs this space addresses in the face 
of extreme climate events and long-term 
impacts

(Contd.)



Climate justice and the built environment418

change impacts interact with pre-existing patterns in society that have resulted in disparities of access to material and 
immaterial resources and opportunities? To what extent is access to some capabilities for some being secured at the 
cost of access to capabilities for others?

Explicit attention to questions about the distribution of capabilities and the means by which they have emerged lays 
the groundwork for the next big question: what opportunities exist in the context of the built environment for decisions 
to be made that would be less likely to result in or perpetuate profound disparity in human capabilities? Pursuing climate 
justice almost certainly requires changing the status quo since many existing systems have fed into or could exacerbate 
injustices which immediately brings up questions about political power and decision-making processes. For example, 
in the face of rapid urbanisation, climate change, and already stretched public service sectors, guaranteeing water 
accessibility for all may require reducing investments in privileged neighbourhoods in order to increase investments in 
systematically disadvantaged areas. However, this type of decision would be likely to face political pressure from those 
who have benefitted from the existing structure and who carry significant political power (Baeza et al. 2019).

Recognising the political nature of climate justice dilemmas de-normalises unjust arrangements and can reorient 
scholars, practitioners, decision-makers and community members towards the mechanisms that initiated and that 
perpetuate systemic injustice. A growing number of scholars have explicitly started to include in-depth attention to the 
political processes both supporting and inhibiting change towards more just arrangements in the built environment 
context (Bulkeley, Edwards, & Fuller 2014; Meerow & Newell 2019; Ziervogel et al. 2017).

Despite the growing attention to issues of climate justice within the built environment community, this literature 
is diverse and rarely shares common notions of equity or justice or even defines these terms. As seen in the suite of 
papers in this special issue, and in the literature broadly, there are many possible ways of integrating justice concerns 
into the built environment. However, due to the diversity of points of interaction between the built environment and 
climate change, ongoing discussions about (in)justice in any given domain are not always linked to each other or to 
broader questions of creating more just social arrangements in an era of climate change. Similarly, even when providing 
in-depth technical insights, many studies do not link such observations directly to issues of justice, and the majority 
of studies quantifying climate change impacts on energy use, comfort, health and wellbeing do not provide detailed 
consideration of the social aspects that magnify risks for health and wellbeing across and within countries (Cheng 
& Berry 2013; Vardoulakis et al. 2015). It is unsurprising that there remain some disciplinary boundaries between 
empirical and normative work in this area. However, all major decisions in the built environment in a context of climate 
change have normative implications. Failing to identify and explore these explicitly misses an opportunity to examine 
how the built environment has shaped inequities or injustices in the climate context, and how this sector could be used 
to reduce potential injustices moving forward.

This editorial uses the notion of a multivalent approach to justice (described below) as a strategy for connecting many 
points of evidence about particular inequities to develop a cohesive and more powerful line of argument about how the 
built environment sector could support efforts towards climate justice.

Built environment support 
for capabilities

Climate change mitigation strategies Climate change adaptation strategies

Sacred sites and cultural amenities Avoid damaging sacred or culturally 
significant sites or amenities when 
developing low-carbon infrastructure; 
reduce emissions related to sacred sites or 
cultural activities

Develop meaningful strategies for 
managing the irreversible loss of sacred 
or culturally significant sites (including 
landscapes)

Essential service infrastructure: Capability to benefit from basic services essential to maintaining personal and social life

At a minimum, essential services would ensure all people can enjoy adequate, accessible, and safe water and sanitation (including 
human and non-human waste systems), food systems and public health

Water and sanitation Ensure low-carbon, safe and adequate water 
and sanitation services 

Protect and/or redesign water and 
sanitation services for resilience in the face 
of extreme climate events and long-term 
impacts; guarantee the health and safety of 
water and sanitation workers even in the 
face of climate impacts

Food systems Invest in human and material infrastructure 
to reduce greenhouse gas emissions of food 
systems through the entire supply chain

Protect and/or redesign food systems 
infrastructure (including for subsistence 
production) for resilience in the face of 
extreme climate events and long-term 
impacts

Public health Ensure adequate low-carbon and accessible 
public health, including minimising 
transportation needs

Ensure public health infrastructure (and 
access to it) is protected from extreme 
climate events or long-term impacts



Klinsky and Mavrogianni 419

5. Multivalent justice
Any number of justice frameworks have been used to help scholars, practitioners, decision-makers and community 
members identify and pursue opportunities to move towards more just arrangements in the context of the built 
environment. For instance, many scholars—including those in this special issue (Baborska-Narozny et al.; Schünemann 
et al.; Willand et al.)—have done in-depth analyses of the distributive implications of decisions in this context as a way of 
making visible the often invisible or overlooked disparities experienced by different individuals or groups of individuals. 
Others have invested energy in asking questions about the types of metrics being used to guide policy making, pointing 
out that how such metrics are designed may in themselves present justice concerns (Axon et al.). Another strategy has 
been to look at decision-making processes as a key element of justice in this context, recognising that who is at the table 
has crucial implications for likely outcomes (Hamstead et al.; Passe et al.; Patrick et al.). All these strategies help us better 
identify existing injustices and, hopefully, imagine and implement ways of addressing these.

This editorial suggests a multivalent approach to justice that includes distributive, procedural and recognition justice 
(Fraser 2001; Schlosberg 2007) may be a useful way to integrate lines of analysis in the justice arena. A multivalent 
approach to justice has been used in several climate related contexts (Klinsky 2015; Klinsky & Winkler 2018; Walker 
2011) including in relation to energy poverty (Walker & Day 2012). A preliminary framework is presented below 
which scholars, practitioners and decision-makers could use to identify and address justice concerns within the built 
environment context:

•	 Distributive justice concerns are the most commonly raised in the climate context and involve any claim based 
on how benefits and burdens are divided across multiple stakeholders. This includes the division of costs and op-
portunities across renters and property owners within a city or claims about the distribution of vulnerability to 
particular impacts, such as heatwaves.

•	 Procedural justice involves all claims about fair, transparent and inclusive decision-making. As with distributive 
justice, procedural justice claims are relevant to all climate change decision contexts. For instance, procedural 
justice could include the integration of undocumented residents in decision-making about adaptation infrastruc-
ture or the involvement of communities in national and international negotiations about profound losses (e.g. 
territory or sacred sites). As already noted in the adaptation context, if processes are not actively designed with 
vulnerable populations, then exclusive adaptation could result, which reinforces rather than reduces pre-exist-
ing inequalities (Meyer et al. 2018). Participatory system dynamics approaches are increasingly adopted in built 
environment research in recent years to facilitate the mapping of complex interactions between key actors and 
 stakeholders (Eker et al. 2018).

•	 Recognition justice emerges in the seemingly mundane but critically important decisions about policy framing and 
analysis. It asks how particular people or groups of people are made visible or invisible in a decision context. Who 
are seen as relevant stakeholders? Which characteristics or specific needs are included in models or frameworks for 
making climate relevant decisions? For instance, it has been argued that migrant workers and those in the informal 
sector have been systematically rendered invisible through state policies, which risks exposing them to even greater 
climate risks (Chu & Michael 2019). Others have pointed out how concepts such as urban sprawl or resilience have 
included or excluded key considerations during their evolution (Borie et al. 2019; Wilson & Chakraborty 2013). For 
researchers, recognition justice requires reflection about the operationalisation of concepts and analytic processes. 
Examples would include decisions about how to include non-monetary losses (such as the loss of culture, health 
or life); the extent to which data disaggregated by gender, ethnicity or any other potential for marginalisation are 
collected and used in climate planning; or the time horizon built into any analyses as this dictates who is ‘seen’ as 
relevant both historically and into the future.

A multivalent approach to justice provides a practical framework for identifying potential injustices and linking them to 
decision-points that could be used to reduce these injustices. Table 3 outlines a simple checklist framework for analysts 
or practitioners to start integrating climate justice into the design and communication of research in the context of 
climate change and the built environment.

To further demonstrate how the proposed framework could be employed by researchers and practitioners in the built 
environment field, two worked examples are provided in Table 4. Similarly, although it did not use this framework 
explicitly, the PCBF is a good example of a recently implemented programme that integrates procedural, recognition 
and distributive justice aims within a climate justice lens (Mondainé & Lee 2020).

This framework allows for a process of moving from observations of inequities to analyses of why these 
happened and how decision processes could address them. In so doing, it also places responsibility on academics to 
acknowledge the considerable power that resides in research to frame an issue. Choices about which issues to focus 
on, which disparities to draw attention to, or which metrics to use are not mere technicalities but determine which 
and whose harms and benefits will become visible. Scholars can use this framework to systematically connect their 
work to that of others who may be looking at different manifestations of climate injustice, but that may involve 
similar causal patterns.



Climate justice and the built environment420

Table 3: Framework for built-environment practitioners and researchers to enable the integration of climate justice 
into decision-making processes.

Justice dimension Core questions

Distributive Are there differences in the distribution of a particular benefit or burden (including risks)? If so, across 
what dimensions are these differences manifest (i.e. income, gender, age, race, location, country, time, 
other social identifiers etc.)?

Are these patterns connected to any other patterns of difference in wellbeing or access to resources?

Where did these disparities come from? Are there processes by which privilege and disadvantage 
accumulated? Are some being protected from risks at the expense of intensification of vulnerability for 
others?

Procedural How have decisions been made that influence the distributions being noticed? 

Who is involved in decision-making, and in what capacities now and over time?

Have some actors had stronger voices in this process than others? How did this occur?

What would need to be put in place to change the capacity for all actors to have a voice in this process?

Recognition What benefits/burdens have been included/excluded in the study or were included/excluded in the 
decision context being examined? Has analysis included means for observing both processes and 
outcomes of decision-making?

Have the appropriate data been collected to enable meaningful comparison across groups?

Which groups of people or aspects of people’s lives are captured by the metrics being used in the decision 
or study context, and which ones are left out? Are there assumptions built into the metrics being used that 
systemically privilege and/or devalue particular people or aspects of people’s lives?

How does this decision or analysis deal with both past accumulation and future needs? 

How does this decision or analysis deal with jurisdictional boundaries and the potential for those outside 
these boundaries to be affected by this decision?

Table 4: Examples of integration of the climate justice framework into the building and urban decision-making pro-
cesses.

Core questions Building-scale example: energy 
retrofit in housing

Urban-scale example: summer 
outdoor thermal comfort

Distributive justice

Are there differences in the distribution 
of a particular benefit or burden? What 
dimensions are these differences manifest 
(i.e. income, gender, age, race, location, 
country, time, other social identifiers etc.)?

Have differences in access to retrofitting 
across any socially relevant indicators in 
this context been checked for?
In addition to the usual factors, retrofit 
decisions often differ across social 
housing and private funding schemes

Have differences in access to 
comfortable outdoor spaces across 
any socially relevant indicators been 
checked for?
Neighbourhood heat vulnerability 
hotspots may have developed over time 
so should be examined explicitly

Are these patterns connected to any other 
patterns of difference in wellbeing or 
access to resources?

In a retrofitting context this may 
including looking at intersections with 
income and rental/homeownership 
patterns

Common intersections to examine 
include race, income and health status 
with geographical proximity to safe 
green space and safe and affordable 
mobility to green/public space

Where did these disparities come from? 
Are there processes by which privilege 
accumulated as well as disadvantage? 
Are some being protected from risks 
at the expense of the creation of more 
vulnerability for others?

Common drivers to examine might 
include rental/home ownership and 
systemic accumulation of disinvestment 
in low income or racialised 
neighbourhoods. Also may need to 
investigate overlap with social benefit 
policies generally

Important to examine the geographical 
distribution of housing in relation to 
green/blue infrastructure investments 
and open public spaces across different 
income bands

(Contd.)



Klinsky and Mavrogianni 421

Core questions Building-scale example: energy 
retrofit in housing

Urban-scale example: summer 
outdoor thermal comfort

Procedural justice

How have decisions been made that 
influence the distributions being noticed? 

How have funding mechanisms (private 
or public), rental regulations, building 
codes, or energy efficiency policies been 
enacted over time?

Have there been lock-in decisions 
such as fixed grids, redlining or other 
segregation policies, risk accumulation 
due to jurisdictional boundaries or 
jurisdictional priority setting over time?

Who is involved in decision-making, and in 
what capacities now and over time?

What actors have been involved 
with these policies, and what have 
the mechanisms been for public 
engagement and representation?

What actors have been involved 
with these policies, and what have 
the mechanisms been for public 
engagement and representation?

Have some actors had stronger voices 
in this process than others? How did 
this occur?

Particularly important groups to look 
at comparatively might include tenants 
and landlords; disadvantaged versus 
privileged residents; industry lobby 
groups versus community organisers 

Residents of lower income and/or 
racialised neighbourhoods are often 
under-represented in planning decisions 
due to structural/institutional injustice. 
Examining how such communities have 
been engaged in all planning processes 
may be important

What would need to be put in place to 
change the capacity for all actors to have a 
voice in this process?

Occupants need to be afforded a voice 
in retrofit uptake decisions. This could 
be achieved through a regulatory 
framework that empowers tenants (e.g. 
the UK’s Energy Act, Minimum Energy 
Efficiency Standards)

Bottom-up citizen influence on 
decision-making could be fostered 
through participative platforms (e.g. 
climate citizen assemblies at the 
borough level).

Recognition justice

What benefits/burdens have been 
included/excluded in the study or were 
included/excluded in the decision context 
being examined? Has analysis included 
means for observing both processes and 
outcomes of decision-making?

This might include looking at outcomes 
such as thermal comfort, household 
spending patterns or aggregate 
health outcomes. Examining process 
might require specific investment in 
process tracing, document analysis or 
other means

This would include looking at 
neighbourhood-level thermal comfort; 
accessibility patterns; and perceived 
safety and inclusion. Examining process 
might require specific investment in 
process tracing, document analysis or 
other means

Have the appropriate data been collected 
to enable meaningful comparison across 
groups ?

What data exist and what is missing? 
New data may need to be collected 
to capture all drivers of potential 
differences

What data exist and what is missing? 
New data may need to be collected 
to capture all drivers of potential 
differences

Which groups of people or aspects of 
people’s lives are captured by the metrics 
being used in the decision or study 
context? Which ones are left out?

This might include incorporating 
people’s economic context (costs, 
budgeting, prioritisation); behaviour 
and desires for living; household coping 
mechanisms or opportunity costs, habits 
and perceptions of energy use into 
analyses

This might include people’s individual 
vulnerability factors along with 
social norms, practices, habits and 
perceptions of urban heat risk, the use 
of existing public space, and desires for 
public space

Are there assumptions built into the 
metrics being used that systemically 
privilege and/or devalue particular people 
or aspects of people’s lives?

For instance, do assumptions about 
‘standard’/normative/rational energy 
use behaviour and retrofit uptake 
decisions fit this context or do they miss 
opportunity costs or lived realities of 
some?

Common assumptions about use of 
public space based only on proportion 
of green coverage and proximity to 
one’s home may devalue some people’s 
use of/desire for green space

How does this decision or analysis deal 
with both past accumulation and future 
needs? 

Has the accumulation of 
privilege/disadvantage been included in 
this analysis? If so, how has this or could 
this be done?

Has the accumulation of 
privilege/disadvantage been included in 
this analysis? If so, how has this or could 
this be done?

How does this decision or analysis deal 
with jurisdictional boundaries and 
the potential for those outside these 
boundaries to be affected by this decision?

How have long-term energy and 
emission patterns and limitations been 
included in decision-making? How 
have other resource demands and their 
implications beyond jurisdictional 
boundaries been considered?

How are broader implications of green 
space provision factored into climate 
action plans or other regional visions? 
If public space is to serve as a water 
management scheme as well, how are 
downstream users represented?



Climate justice and the built environment422

6. Contributions to knowledge of this special issue
With the intent of facilitating greater integration between work on the built environment and climate justice, this 
special issue brings together a set of studies (Table 1) aiming to frame built environment sector-related aspects of 
climate change within a climate justice concept framework. Several themes emerge from this body of work. As discussed 
above, distributive justice in the climate and built environment context may refer to costs (Baborska-Narozny et al.), 
opportunities (Willand et al.) or climate vulnerability distribution (Axon et al.). Baborska-Narozny et al. quantify the costs 
of a transition from solid fuel heating to other heating fuel types for disadvantaged households in Wroclaw, Poland. 
Such policies are mainly driven by combined carbon emissions and air pollution reduction policy targets. Unfortunately, 
they may lead to the unintended consequence of increasing fuel costs for lower income residents of social housing, 
where solid fuels are more common, thus further contributing to fuel poverty and magnifying existing inequalities. 
Similar concerns about the cost implications of energy transitions on low income communities are expressed by Axon 
et al.; their mixed methods study evaluates the impact of the implementation of a biomass energy system in low income 
housing near Liverpool, UK. The authors highlight the need to shift the focus from energy efficiency metrics primarily 
rooted to environmental and economic drivers to a more holistic consideration of just, community inclusive processes 
that do not amplify underlying inequalities. Willand et al. introduce the concept of retrofit poverty, a household’s 
opportunities to access retrofit funding, as a distributive justice issue. Opportunities to improve the energy and thermal 
performance of one’s home are not equally distributed across households. Through the analysis of home energy 
certificate data for the residential stock of Victoria, Australia, the study found that energy retrofit uptake was lower in 
areas with higher proportion of renters and lower income households. The authors stress the need to consider the ways 
in which market-based retrofit subsidies work; whilst they might result in comfort improvements, energy and carbon 
savings, the fact that these may not be enjoyed equally by all income groups can exacerbate underlying disparities. 
Schünemann et al. assess the effects of thermal retrofits on winter and summer thermal comfort, and associated 
energy use and carbon emissions, in typical multifamily housing units in Germany. They emphasise the importance 
of co-creating climate adaptation solutions with the inhabitants. For instance, particular attention needs to be paid 
to dwellings that rely on occupant controlled natural ventilation strategies for cooling. If ventilation strategies are not 
appropriately implemented, residents who have limited adaptive capacity will experience an increasing risk of summer 
indoor overheating as the climate becomes warmer, which will increase their vulnerability to climate change.

Other papers in this special issue explore the nexus of procedural and recognition climate justice in the context of built 
environment decision-making (Hamstead et al.; Passe et al.; Patrick et al.). Hamstead et al. investigate the socio-technical 
and governance challenges that urban communities face as a result of extreme heat events. They use actor–network 
theory as the basis for the development of a decision-making framework for urban planning decisions in Arizona and 
New York. This framework recognises the justice aspects of climate change adaptation policy actions in order to build 
urban environments and communities that are well prepared for periods of excess heat. Another decision-making 
framework that embeds socio-technical information and capabilities for heat resilient urban environments is presented 
by Passe et al. focusing on disadvantaged neighbourhoods in Iowa. It is envisaged that such human-centred frameworks 
will facilitate the integration of human behaviour, socio-demographic and urban neighbourhood characteristics in 
socially just climate adaptation planning. Patrick et al. adopt an ecofeminist approach and uses a case study in rural 
Kenya to discuss the development of a conceptual and practical framework for the design of integrated solutions that 
tackle planetary health injustices; building design is presented as a tool that could promote equity, justice, health and 
climate change adaptation.

7. Current challenges for the built environment
Several specific areas for further work emerge from this special issue, relating particularly to how the broader built 
environment community might contribute to a more just future in the context of climate change. We invite stakeholders 
involved in this sector to consider how they might fit within these specific challenges and arenas of activity.

7.1. Governance and advocacy
•	 Governing bodies need to clearly establish and formally recognise existing commitments to protect vulnerable people 

in the context of climate change. There may also be a role for professional associations, education and training insti-
tutions, and regulatory authorities to ensure professionals are explicitly aware of their role and responsibilities for 
guaranteeing human rights and the capabilities of all people even in the context of climate change. This includes 
obligations for the protection of all human rights, as well as to the non-discriminatory enjoyment of public services, 
including those provided through disasters and public health emergencies. Existing commitments upon which 
such obligations could be explicitly connected include the UN Declaration of Human Rights, commitments to the 
SDGs, and, where relevant, commitments to the UN Declaration on the Rights of Indigenous Peoples (UNDRIP). No-
tably, particularly in the context of UNDRIP, this includes respecting free, prior and informed consent from relevant 
Indigenous populations for all infrastructure development on their traditional lands and territories.

•	 Feasible and equitable pathways need to be implemented for the provision of healthy, low-carbon, climate resilient 
outdoor and indoor environments for vulnerable population groups in a changing climate. This will require the use 
of evaluation methods for planning and implementation that can capture the range of justice issues, including 



Klinsky and Mavrogianni 423

those that manifest through inequities in climate risk exposures, vulnerabilities, and adaptive capacity relevant to 
any project. It will also feature strong participatory efforts to ensure that the needs and concerns of those who are 
most vulnerable are integrated into decision-making. The multivalent framework presented above (Table 2) could 
be one such evaluation tool that is designed to be very flexible, although others could also be used depending on 
the situation.

•	 Authorities need to regulate climate risks that impact beyond their jurisdictional boundary. Built environment activities 
benefitting those in their own jurisdictions must not impose harm on those beyond their boundaries (e.g. through sup-
ply chains or other forms of risk displacement). Working with networks of jurisdictions may be one strategy for this. 
There may also be a role for professional associations to mandate their members’ actions to account for all climate 
risks regardless of jurisdictional boundaries.

•	 Governing bodies (including regulatory authorities or professional associations where relevant) need to establish 
redress processes for vulnerable people. If a failure to meet obligations and responsibilities occurs, then a recourse 
to seek justice is necessary.

7.2. Documentation and analysis
•	 There is a pressing need to systematically map existing currently fragmented research on climate risk exposures and 

vulnerabilities by socio-demographic features both across and within countries, and their implications on social 
inequalities/inequities and human development in the context of ongoing and future climate change. Gathering 
documentation of inequities is already starting to occur in this sector, which creates a baseline upon which further 
work could build. There is a clear call for researchers and for governing bodies at all levels to cooperate to conduct 
quality analyses, which includes generating and providing appropriately disaggregated high-quality data.

•	 In light of the systemic nature of injustice underpinning many inequitable outcomes, there is currently insufficient 
data and analysis on the systemic barriers to access and implementation challenges of interventions for vulnerable 
populations. For example, many authors (Cayla, Maizi, & Marchand 2011; Gillard et al. 2017; Schaffrin & Reibling 
2015) have pointed out that a deeper understanding of individual needs, behaviour patterns and energy use prac-
tices in buildings across different income groups, and their relationship to contextual factors (e.g. welfare regimes, 
housing systems etc.) is required. This would include research that quantifies the adaptive capacity of different 
socio-demographic groups (based on age, gender, ethnicity, income, health status, social deprivation index etc.) 
to lessen the adverse impacts of climate change, and that critically identifies the root causes of these inequalities.

•	 There is also a need for researchers and governing bodies to actively make analyses of risk exposures and of systemic 
barriers publicly available in order to support meaningful participation in further decision-making. To accelerate 
the impact of research outcomes, outputs tailored to specific key audiences (policymakers, built environment and 
public health practitioners, citizens) will need to be co-created through knowledge exchange. Institutions that sup-
port and incentivise researchers (including through non-monetary forms of recognition), including universities and 
funding bodies, also have a role to play in ensuring that such information is made readily available.

7.3. Training and capacity-building
•	 Academic and training programmes charged with training professionals involved in planning, designing and imple-

menting built environment projects should ensure all trainees are equipped with awareness of inequities and social 
injustices generally and particularly in the context of climate change. Further integration of justice concerns into 
this sector will be hampered without foundational understanding of the core issues across all relevant professions.

•	 The environmental health and wellbeing discourse must further integrate the built environment into assessments of 
social and health inequities. Health and social assessments, particularly in the context of climate change require 
interdisciplinary thinking between researchers working in the areas of built environment, health, social justice, 
industry, policymakers, non-governmental organisations (NGOs) and communities. Such interdisciplinarity work 
requires conceptual, financial and institutional support. There is a role for all relevant institutions, professional 
associations, and funders to support such integration.

Climate change will inevitably pose a range of pressures on existing systems that already result in inequities. Stakeholders 
in the built environment sector have significant roles to play in moving towards a more just future to protect the 
vulnerable and ensure their wellbeing. Although the principles of climate justice may be new to some in the built 
environment, the scale and urgency of this responsibility is a mainstream issue for our buildings, infrastructure, towns 
and cities to remain viable, useable and adaptable. The design, operation, maintenance and use of built environment 
must afford protection to society—both now and in future. In light of current and predicted climate change, it is vital 
that decisions and actions do not hurt or disadvantage those most vulnerable within a society and those societies that 
will be negatively impacted, now and in the future. This special issue helps to initiate a discourse about the research, 
guidance and actions that will be needed. Further research and policy analysis contributions to this journal are welcome.

Acknowledgements
The authors acknowledge the valuable comments and editorial assistance provided by Richard Lorch.



Climate justice and the built environment424

Competing interests
The authors have no competing interests.

References
Agarwal, A., & Narain, S. (1991). Global warming in an unequal world: A case of environmental colonialism. Delhi: 

Centre for Science and Environment.
Anguelovski, I., Irazábal-Zurita, C., & Connolly, J. J. T. (2019). Grabbed urban landscapes: Socio-spatial tensions 

in green infrastructure planning in Medellín. International Journal of Urban Regional Research, 43, 133–156. DOI: 
https://doi.org/10.1111/1468-2427.12725

Baeza, A., Bojorquez-Tapia, L. A., Janssen, M. A., & Eakin, H. (2019). Operationalizing the feedback between 
institutional decision-making, socio-political infrastructure, and environmental risk in urban vulnerability analysis. 
Journal of Environmental Management, 241, 407–417. DOI: https://doi.org/10.1016/j.jenvman.2019.03.138

Baker, J. L. (2012). Climate change, disaster risk, and the urban poor, urban development. World Bank. DOI: https://doi.
org/10.1596/978-0-8213-8845-7

BASIC Experts. (2011). Equitable access to sustainable development: Contribution to the body of scientific knowledge. 
BASIC Expert Group. http://gdrights.org/wp-content/uploads/2011/12/EASD-final.pdf

Borie, M., Pelling, M., Ziervogel, G., & Hyams, K. (2019). Mapping narratives of urban resilience in the Global South. 
Global Environmental Change, 54, 203–213. DOI: https://doi.org/10.1016/j.gloenvcha.2019.01.001

Bulkeley, H., Edwards, G. A. S., & Fuller, S. (2014). Contesting climate justice in the city: Examining politics and practice 
in urban climate change experiments. Global Environmental Change, 25, 31–40. DOI: https://doi.org/10.1016/j.
gloenvcha.2014.01.009

Byrne, J., Ambrey, C., Portanger, C., Lo, A., Matthews, T., Baker, D., & Davison, A. (2016). Could urban greening 
mitigate suburban thermal inequity?: The role of residents’ dispositions and household practices. Environmental 
Research Letters, 11, 095014. DOI: https://doi.org/10.1088/1748-9326/11/9/095014

Cameron, E. S. (2012). Securing Indigenous politics: A critique of the vulnerability and adaptation approach to the 
human dimensions of climate change in the Canadian Arctic. Global Environmental Change, 22, 103–114. DOI: 
https://doi.org/10.1016/j.gloenvcha.2011.11.004

Camprubí, L., Malmusi, D., Mehdipanah, R., Palència, L., Molnar, A., Muntaner, C., & Borrell, C. (2016). Façade 
insulation retrofitting policy implementation process and its effects on health equity determinants: A realist review. 
Energy Policy, 91, 304–314. DOI: https://doi.org/10.1016/j.enpol.2016.01.016

Cayla, J.-M., Maizi, N., & Marchand, C. (2011). The role of income in energy consumption behaviour: Evidence 
from French households data. Energy Policy, Clean Cooking Fuels and Technologies in Developing Economies, 39, 
7874–7883. DOI: https://doi.org/10.1016/j.enpol.2011.09.036

Cheng, J. J., & Berry, P. (2013). Health co-benefits and risks of public health adaptation strategies to climate change: 
A review of current literature. International Journal of Public Health, 58, 305–311. DOI: https://doi.org/10.1007/
s00038-012-0422-5

Chu, E., & Michael, K. (2019). Recognition in urban climate justice: Marginality and exclusion of migrants in Indian 
cities. Environment and Urbanization, 31, 139–156. DOI: https://doi.org/10.1177/0956247818814449

CJN! (2004). Climate Justice Now! A call for people’s action against climate change. Climate Justice Now! Retrieved from 
http://climatejustice.blogspot.com/2004_11_23_archive.html

Cole, H. V. S., Lamarca, M. G., Connolly, J. J. T., & Anguelovski, I. (2017). Are green cities healthy and equitable? 
Unpacking the relationship between health, green space and gentrification. Journal of Epidemiology and Community 
Health, 71, 1118–1121. DOI: https://doi.org/10.1136/jech-2017-209201

Deng, H.-M., Liang, Q.-M., Liu, L.-J., & Anadon, L. D. (2017). Co-benefits of greenhouse gas mitigation: A review and 
classification by type, mitigation sector, and geography. Environmental Research Letters, 12, 123001. DOI: https://
doi.org/10.1088/1748-9326/aa98d2

Eker, S., Zimmermann, N., Carnohan, S., & Davies, M. (2018). Participatory system dynamics modelling for housing, 
energy and wellbeing interactions. Building Research & Information, 46, 738–754. DOI: https://doi.org/10.1080/0
9613218.2017.1362919

Escandón, R., Suárez, R., & Sendra, J. J. (2019). Field assessment of thermal comfort conditions and energy performance 
of social housing: The case of hot summers in the Mediterranean climate. Energy Policy, 128, 377–392. DOI: https://
doi.org/10.1016/j.enpol.2019.01.009

Field, C. B., Barros, V. R., Mach, K. J., Mastrandrea, M. D., van Aalst, M., Adger, W. N., Arent, D. J., Barnett, J., 
Betts, R., Bilir, T. E., Birkmann, J., Carmin, J., Chadee, D. D., Challinor, A. J., Chatterjee, M., Cramer, W., 
Davidson, D. J., Estrada, Y. O., Gattuso, J.-P., Hijioka, Y., Hoegh-Guldberg, O., Huang, H.-Q., Insarov, G. E., 
Jones, R. N., Kovats, R. S., Lankao, P. R., Larsen, J. N., Losada, I. J., Marengo, J. A., McLean, R. F., Mearns, L. 
O., Mechler, R., Morton, J. F., Niang, I., Oki, T., Olwoch, J. M., Opondo, M., Poloczanska, E. S., Pörtner, H.-O., 
Redsteer, M. H., Reisinger, A., Revi, A., Schmidt, D. N., Shaw, M. R., Solecki, W., Stone, D. A., Stone, J. M. R., 
Strzepek, K. M., Suarez, A. G., Tschakert, P., Valentini, R., Vicuña, S., Villamizar, A., Vincent, K. E., Warren, 
R., White, L. L., Wilbanks, T. J., Wong, P. P., & Yohe, G. W. (2014). Technical summary. In Field, C. B., Barros, V. 

https://doi.org/10.1111/1468-2427.12725
https://doi.org/10.1016/j.jenvman.2019.03.138
https://doi.org/10.1596/978-0-8213-8845-7
https://doi.org/10.1596/978-0-8213-8845-7
http://gdrights.org/wp-content/uploads/2011/12/EASD-final.pdf
https://doi.org/10.1016/j.gloenvcha.2019.01.001
https://doi.org/10.1016/j.gloenvcha.2014.01.009
https://doi.org/10.1016/j.gloenvcha.2014.01.009
https://doi.org/10.1088/1748-9326/11/9/095014
https://doi.org/10.1016/j.gloenvcha.2011.11.004 
https://doi.org/10.1016/j.enpol.2016.01.016
https://doi.org/10.1016/j.enpol.2011.09.036
https://doi.org/10.1007/s00038-012-0422-5
https://doi.org/10.1007/s00038-012-0422-5
https://doi.org/10.1177/0956247818814449
http://climatejustice.blogspot.com/2004_11_23_archive.html
https://doi.org/10.1136/jech-2017-209201
https://doi.org/10.1088/1748-9326/aa98d2
https://doi.org/10.1088/1748-9326/aa98d2
https://doi.org/10.1080/09613218.2017.1362919
https://doi.org/10.1080/09613218.2017.1362919
https://doi.org/10.1016/j.enpol.2019.01.009
https://doi.org/10.1016/j.enpol.2019.01.009


Klinsky and Mavrogianni 425

R., Dokken, D. J., Mach, K. J., Mastrandrea, M. D., Bilir, T. E., Chatterjee, M., Ebi, K. L., Estrada, Y. O., Genova, R. C., 
Girma, B., Kissel, E. S., Levy, A. N., MacCracken, S., Mastrandrea, P. R., & White, L. L. (Eds.). Climate change 2014: 
Impacts, adaptation, and vulnerability. Part A: Global and sectoral aspects. Contribution of Working Group II to the 
Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press.

Forde, J., Hopfe, C. J., McLeod, R. S., & Evins, R. (2020). Temporal optimization for affordable and resilient 
Passivhaus dwellings in the social housing sector. Applied Energy, 261, 114383. DOI: https://doi.org/10.1016/j.
apenergy.2019.114383

Fraser, N. (2001). Recognition without ethics? Theory, Culture and Society, 18, 21–42. DOI: https://doi.
org/10.1177/02632760122051760

Friel, S., Dangour, A. D., Garnett, T., Lock, K., Chalabi, Z., Roberts, I., Butler, A., Butler, C. D., Waage, J., 
McMichael, A. J., & Haines, A. (2009). Public health benefits of strategies to reduce greenhouse-gas emissions: 
Food and agriculture. Lancet, 374, 2016–2025. DOI: https://doi.org/10.1016/S0140-6736(09)61753-0

Fussell, E., Sastry, N., & Van Landingham, M. (2010). Race, socioeconomic status, and return migration to New Orleans 
after Hurricane Katrina. Population and Environment, 31, 20–42. DOI: https://doi.org/10.1007/s11111-009-0092-2

Gao, J., Kovats, S., Vardoulakis, S., Wilkinson, P., Woodward, A., Li, J., Gu, S., Liu, X., Wu, H., Wang, J., Song, X., 
Zhai, Y., Zhao, J., & Liu, Q. (2018). Public health co-benefits of greenhouse gas emissions reduction: A systematic 
review. Science of the Total Environment, 627, 388–402. DOI: https://doi.org/10.1016/j.scitotenv.2018.01.193

Gardiner, S. (2006). A perfect moral storm. Environmental Values, 15, 397–413. DOI: https://doi.
org/10.3197/096327106778226293

Gibson, A. (2019). Climate change for individuals experiencing homelessness: Recommendations for improving policy, 
research, and services. Environmental Justice, 12, 159–163. DOI: https://doi.org/10.1089/env.2018.0032

Gillard, R., Snell, C., & Bevan, M. (2017). Advancing an energy justice perspective of fuel poverty: Household 
vulnerability and domestic retrofit policy in the United Kingdom. Energy Research and Social Science, 29, 53–61. 
DOI: https://doi.org/10.1016/j.erss.2017.05.012

Grear, A. (2014). Towards ‘climate justice’? A critical reflection on legal subjectivity and climate injustice: warning 
signals, patterned hierarchies, directions for future law and policy. Journal of Human Rights and the Environment, 5, 
103-133. DOI: https://doi.org/10.4337/jhre.2014.02.08

Gütschow, J., Jeffery, M. L., Gieseke, R., Gebel, R., Stevens, D., Krapp, M., & Rocha, M. (2016). The PRIMAP-hist 
national historical emissions time series. Earth System Science Data, 8, 571–603. DOI: https://doi.org/10.5194/
essd-8-571-2016

Haines, A., McMichael, A. J., Smith, K. R., Roberts, I., Woodcock, J., Markandya, A., Armstrong, B. 
G., Campbell-Lendrum, D., Dangour, A. D., Davies, M., Bruce, N., Tonne, C., Barrett, M., & Wilkinson, P. 
(2009). Public health benefits of strategies to reduce greenhouse-gas emissions: Overview and implications for 
policy makers. Lancet, 374, 2104–2114. DOI: https://doi.org/10.1016/S0140-6736(09)61759-1

Haines, A., Smith, K. R., Anderson, D., Epstein, P. R., McMichael, A. J., Roberts, I., Wilkinson, P., Woodcock, J., 
& Woods, J. (2007). Policies for accelerating access to clean energy, improving health, advancing development, and 
mitigating climate change. Lancet, 370, 1264–1281. DOI: https://doi.org/10.1016/S0140-6736(07)61257-4

Hale, M. R. (2019). Fountains for environmental justice: Public water, homelessness, and migration in the face of global 
environmental change. Environmental Justice, 12, 33–40. DOI: https://doi.org/10.1089/env.2018.0031

Henrique, K. P., & Tschakert, P. (2019). Contested grounds: Adaptation to flooding and the politics of (in)visibility 
in São Paulo’s eastern periphery. Geoforum, 104, 181–192. DOI: https://doi.org/10.1016/j.geoforum.2019.04.026

Howden-Chapman, P., Matheson, A., Crane, J., Viggers, H., Cunningham, M., Blakely, T., Cunningham, C., 
Woodward, A., Saville-Smith, K., O’Dea, D., Kennedy, M., Baker, M., Waipara, N., Chapman, R., & Davie, G. 
(2007). Effect of insulating existing houses on health inequality: Cluster randomised study in the community. British 
Medical Journal, 334, 460–464. DOI: https://doi.org/10.1136/bmj.39070.573032.80

ICJN. (2002). Bali Principles of Climate Justice. International Climate Justice Network (IJCN). Retrieved from http://
www.indiaresource.org/issues/energycc/2003/baliprinciples.html

IPCC. (2018). Global warming of 1.5°C. An IPCC special report on the impacts of global warming of 1.5°C above pre-industrial 
levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the 
threat of climate change, sustainable development, and efforts to eradicate poverty. [Masson-Delmotte, V., P. Zhai, 
H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. 
Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds)]. Intergovernmental 
Panel on Climate Change (IPCC). https://www.ipcc.ch/sr15/

Islam, S. N., & Winkel, J. (2017). Climate Change and Social Inequality (Working Paper No. 152 ST/ESA/2017/
DWP/152, October). Department of Economic & Social Affairs (DESA). Retrieved from https://www.un.org/esa/
desa/papers/2017/wp152_2017.pdf

IWBI. (2016). The WELL building standard v1 with May 2016 addenda. International WELL Building Institute (IWBI), 
Delos Living LLC.

Kelman, I. (2020). Disaster by choice: How our actions turn natural hazards into catastrophes. Oxford University Press.

https://doi.org/10.1016/j.apenergy.2019.114383
https://doi.org/10.1016/j.apenergy.2019.114383
https://doi.org/10.1177/02632760122051760
https://doi.org/10.1177/02632760122051760
https://doi.org/10.1016/S0140-6736(09)61753-0
https://doi.org/10.1007/s11111-009-0092-2
https://doi.org/10.1016/j.scitotenv.2018.01.193
https://doi.org/10.3197/096327106778226293
https://doi.org/10.3197/096327106778226293
https://doi.org/10.1089/env.2018.0032
https://doi.org/10.1016/j.erss.2017.05.012
https://doi.org/10.4337/jhre.2014.02.08
https://doi.org/10.5194/essd-8-571-2016
https://doi.org/10.5194/essd-8-571-2016
https://doi.org/10.1016/S0140-6736(09)61759-1
https://doi.org/10.1016/S0140-6736(07)61257-4
https://doi.org/10.1089/env.2018.0031
https://doi.org/10.1016/j.geoforum.2019.04.026
https://doi.org/10.1136/bmj.39070.573032.80
http://www.indiaresource.org/issues/energycc/2003/baliprinciples.html
http://www.indiaresource.org/issues/energycc/2003/baliprinciples.html
https://www.ipcc.ch/sr15/
https://www.un.org/esa/desa/papers/2017/wp152_2017.pdf
https://www.un.org/esa/desa/papers/2017/wp152_2017.pdf


Climate justice and the built environment426

Klinsky, S. (2015). Justice and boundary setting in greenhouse gas cap and trade policy: A case study of the western 
climate initiative. Annals of the Association of American Geographers, 105, 105–122. DOI: https://doi.org/10.1080/
00045608.2014.960043

Klinsky, S., & Winkler, H. (2018). Building equity in: Strategies for integrating equity into modelling for a 1.5°C world. 
Philosophical Transactions of the Royal Society A, 376, 20160461. DOI: https://doi.org/10.1098/rsta.2016.0461

Kolosna, C., & Spurlock, D. (2019). Uniting geospatial assessment of neighborhood urban tree canopy with plan and 
ordinance evaluation for environmental justice. Urban Forestry and Urban Greening, 40, 215–223. DOI: https://doi.
org/10.1016/j.ufug.2018.11.010

LaRovere, E., Valente de Macedo, L., & Baumert, K. (2002). The Brazilian proposal on relative responsibility for 
global warming. In Baumert, K. A., Blanchard, O., Llosa, S., & Perkaus, J. (Eds.), Building on the Kyoto Protocol: Options 
for protecting the climate (pp. 157–173). World Resources Institute.

Madianou, M. (2015). Digital inequality and second-order disasters: Social media in the Typhoon Haiyan recovery. 
Social Media Society, 1, 2056305115603386. DOI: https://doi.org/10.1177/2056305115603386

Mallaburn, P. S., & Eyre, N. (2014). Lessons from energy efficiency policy and programmes in the UK from 1973 to 
2013. Energy Efficiency, 7, 23–41. DOI: https://doi.org/10.1007/s12053-013-9197-7

Malm, A. (2013). The origins of fossil capital: From water to steam in the British cotton industry. Historical Materialism, 
21, 15–68. DOI: https://doi.org/10.1163/1569206X-12341279

Markandya, A., Armstrong, B. G., Hales, S., Chiabai, A., Criqui, P., Mima, S., Tonne, C., & Wilkinson, P. (2009). 
Public health benefits of strategies to reduce greenhouse-gas emissions: low-carbon electricity generation. Lancet, 
374, 2006–2015. DOI: https://doi.org/10.1016/S0140-6736(09)61715-3

Markkanen, S., & Anger-Kraavi, A. (2019). Social impacts of climate change mitigation policies and their implications 
for inequality. Climate Policy, 19, 827–844. DOI: https://doi.org/10.1080/14693062.2019.1596873

Marmot, M., Allen, J., Goldblatt, P., Boyce, T., McNeish, D., Grady, M., & Geddes, I. (2010). Fair society healthy lives: 
The Marmot Review, strategic review of health inequalities in England post-2010. Institute of Health Equity, University 
College London (UCL).

Marsh, R. (2017). Building lifespan: Effect on the environmental impact of building components in a Danish 
perspective. Architecture and Engineering Design Management, 13, 80–100. DOI: https://doi.org/10.1080/174520
07.2016.1205471

Meerow, S., & Newell, J. P. (2019). Urban resilience for whom, what, when, where, and why? Urban Geography, 40, 
309–329. DOI: https://doi.org/10.1080/02723638.2016.1206395

Meyer, M. A., Hendricks, M., Newman, G. D., Hicks Masterson, J., Cooper, J. T., Sansom, G., Gharaibeh, N., et 
al. (2018). Participatory action research: Tools for disaster resilience education. International Journal of Disaster 
Resilience in the Built Environment, 9(4–5), 402–419. DOI: https://doi.org/10.1108/IJDRBE-02-2017-0015

Milner, J., Hamilton, I., Woodcock, J., Williams, M., Davies, M., Wilkinson, P., & Haines, A. (2020). Health benefits 
of policies to reduce carbon emissions. British Medical Journal, 368. DOI: https://doi.org/10.1136/bmj.l6758

Mitchell, B. C., & Chakraborty, J. (2015). Landscapes of thermal inequity: Disproportionate exposure to 
urban heat in the three largest US cities. Environmental Research Letters, 10, 115005. DOI: https://doi.
org/10.1088/1748-9326/10/11/115005

Mondainé, E. D., & Lee, M. (2020). Commentary: Beyond theory: Climate justice in practice. Buildings & Cities. https://
www.buildingsandcities.org/insights/commentaries/beyond-theory-climate-justice-practice.html

Nussbaum, M. C. (2011). Capabilities, entitlements, rights: Supplementation and critique. Journal of Human 
Development Capabilities, 12, 23–37. DOI: https://doi.org/10.1080/19452829.2011.541731

Perdue, W. C., Stone, L. A., & Gostin, L. O. (2003). The built environment and its relationship to the public’s 
health: The legal framework. American Journal of Public Health 93, 1390–1394. DOI: https://doi.org/10.2105/
AJPH.93.9.1390

Power, A. (2008). Does demolition or refurbishment of old and inefficient homes help to increase our environmental, 
social and economic viability? Energy Policy, Foresight Sustainable Energy Management and the Built Environment 
Project, 36, 4487–4501. DOI: https://doi.org/10.1016/j.enpol.2008.09.022

Romero Lankao, P., & Qin, H. (2011). Conceptualizing urban vulnerability to global climate and environmental change. 
Current Opinions in Environmental Sustainability, 3, 142–149. DOI: https://doi.org/10.1016/j.cosust.2010.12.016

Saad, A. (2017). Toward a justice framework for understanding and responding to climate migration and displacement. 
Environmental Justice, 10, 98–101. DOI: https://doi.org/10.1089/env.2016.0033

Sánchez-Guevara Sánchez, C., Mavrogianni, A., & Neila González, F. J. (2017). On the minimal thermal habitability 
conditions in low income dwellings in Spain for a new definition of fuel poverty. Building and Environment, 114, 
344–356. DOI: https://doi.org/10.1016/j.buildenv.2016.12.029

Sandberg, N. H., Sartori, I., Heidrich, O., Dawson, R., Dascalaki, E., Dimitriou, S., Vimm-r, T., Filippidou, F., 
Stegnar, G., Šijanec Zavrl, M., & Brattebø, H. (2016). Dynamic building stock modelling: Application to 11 
European countries to support the energy efficiency and retrofit ambitions of the EU. Energy and Buildings, 132, 
26–38. DOI: https://doi.org/10.1016/j.enbuild.2016.05.100

https://doi.org/10.1080/00045608.2014.960043
https://doi.org/10.1080/00045608.2014.960043
https://doi.org/10.1098/rsta.2016.0461
https://doi.org/10.1016/j.ufug.2018.11.010
https://doi.org/10.1016/j.ufug.2018.11.010
https://doi.org/10.1177/2056305115603386
https://doi.org/10.1007/s12053-013-9197-7
https://doi.org/10.1163/1569206X-12341279
https://doi.org/10.1016/S0140-6736(09)61715-3
https://doi.org/10.1080/14693062.2019.1596873
https://doi.org/10.1080/17452007.2016.1205471
https://doi.org/10.1080/17452007.2016.1205471
https://doi.org/10.1080/02723638.2016.1206395
https://doi.org/10.1108/IJDRBE-02-2017-0015
https://doi.org/10.1136/bmj.l6758
https://doi.org/10.1088/1748-9326/10/11/115005
https://doi.org/10.1088/1748-9326/10/11/115005
https://www.buildingsandcities.org/insights/commentaries/beyond-theory-climate-justice-practice.html 
https://www.buildingsandcities.org/insights/commentaries/beyond-theory-climate-justice-practice.html 
https://doi.org/10.1080/19452829.2011.541731
https://doi.org/10.2105/AJPH.93.9.1390
https://doi.org/10.2105/AJPH.93.9.1390
https://doi.org/10.1016/j.enpol.2008.09.022
https://doi.org/10.1016/j.cosust.2010.12.016
https://doi.org/10.1089/env.2016.0033
https://doi.org/10.1016/j.buildenv.2016.12.029
https://doi.org/10.1016/j.enbuild.2016.05.100


Klinsky and Mavrogianni 427

Schaffrin, A. (2013). Who pays for climate mitigation? An empirical investigation on the distributional effects 
of climate policy in the housing sector. Energy and Buildings, 59, 265–272. DOI: https://doi.org/10.1016/j.
enbuild.2012.12.033

Schaffrin, A., & Reibling, N. (2015). Household energy and climate mitigation policies: Investigating energy practices 
in the housing sector. Energy Policy, 77, 1–10. DOI: https://doi.org/10.1016/j.enpol.2014.12.002

Schlosberg, D. (2007). Defining environmental justice: Theories, movements, and nature. Oxford University Press. DOI: 
https://doi.org/10.1093/acprof:oso/9780199286294.001.0001

Sen, A. (1999). Development as freedom. Oxford University Press.
Sen, A. (2005). Human rights and capabilities. Journal of Human Development, 6, 151–166. DOI: https://doi.

org/10.1080/14649880500120491
Sharkey, P. (2007). Survival and death in New Orleans: An empirical look at the human impact of Katrina. Journal of 

Black Studies, 37, 482–501. DOI: https://doi.org/10.1177/0021934706296188
Smith, K. R., Jerrett, M., Anderson, H. R., Burnett, R. T., Stone, V., Derwent, R., Atkinson, R. W., Cohen, A., 

Shonkoff, S. B., Krewski, D., Pope, C. A., Thun, M. J., & Thurston, G. (2009). Public health benefits of strategies 
to reduce greenhouse-gas emissions: Health implications of short-lived greenhouse pollutants. Lancet, 374, 
2091–2103. DOI: https://doi.org/10.1016/S0140-6736(09)61716-5

Smith, P., & Henríquez, C. (2019). Public spaces as climate justice places? Climate quality in the city of Chillán, Chile. 
Environmental Justice, 12, 164–174. DOI: https://doi.org/10.1089/env.2018.0041

Tabata, T., & Tsai, P. (2020). Fuel poverty in summer: An empirical analysis using microdata for Japan. Science of the 
Total Environment, 703, 135038. DOI: https://doi.org/10.1016/j.scitotenv.2019.135038

Teli, D., Dimitriou, T., James, P., Bahaj, A., Ellison, L., & Waggott, A. (2016). Fuel poverty-induced ‘prebound effect’ 
in achieving the anticipated carbon savings from social housing retrofit. Building Services and Engineering Research 
Technology, 37, 176–193. DOI: https://doi.org/10.1177/0143624415621028

Thomson, H., Simcock, N., Bouzarovski, S., & Petrova, S. (2019). Energy poverty and indoor cooling: An overlooked 
issue in Europe. Energy and Buildings, 196, 21–29. DOI: https://doi.org/10.1016/j.enbuild.2019.05.014

Tozer, L. (2020). Catalyzing political momentum for the effective implementation of decarbonization for urban 
buildings. Energy Policy, 136, 111042. DOI: https://doi.org/10.1016/j.enpol.2019.111042

Tschakert, P., van Oort, B., Clair, A. L. S., & LaMadrid, A. (2013). Inequality and transformation analyses: A 
complementary lens for addressing vulnerability to climate change. Climate and Development, 5, 340–350. DOI: 
https://doi.org/10.1080/17565529.2013.828583

Turan, Z. (2018). Finding the ‘local green voice’? Waterfront development, environmental justice, and 
participatory planning in Gowanus, NY. Urbani Izziv, 29, 79–94. DOI: https://doi.org/10.5379/
urbani-izziv-en-2018-29-supplement-005

UN. (2015). Transforming our world: The 2030 Agenda for Sustainable Development, Resolution adopted by the General 
Assembly on 25 September 2015. United Nations (UN). DOI: https://doi.org/10.1891/9780826190123.ap02

Ürge-Vorsatz, D., & Tirado Herrero, S. (2012). Building synergies between climate change mitigation and energy 
poverty alleviation. Energy Policy, 49, 83–90. DOI: https://doi.org/10.1016/j.enpol.2011.11.093

Vardoulakis, S., Dimitroulopoulou, C., Thornes, J., Lai, K.-M., Taylor, J., Myers, I., Heaviside, C., Mavrogianni, 
A., Shrubsole, C., Chalabi, Z., Davies, M., & Wilkinson, P. (2015). Impact of climate change on the domestic 
indoor environment and associated health risks in the UK. Environment International, 85, 299–313. DOI: https://
doi.org/10.1016/j.envint.2015.09.010

Walker, G. (2011). Environmental justice. Routledge.
Walker, G., & Day, R. (2012). Fuel poverty as injustice: Integrating distribution, recognition and procedure in the 

struggle for affordable warmth. Energy Policy, 49, 69–75. DOI: https://doi.org/10.1016/j.enpol.2012.01.044
Wang, J., Zhang, Y., & Wang, Y. (2018). Environmental impacts of short building lifespans in China considering time 

value. Journal of Cleaner Production, 203, 696–707. DOI: https://doi.org/10.1016/j.jclepro.2018.08.314
Watts, N., Amann, M., Arnell, N., Ayeb-Karlsson, S., Belesova, K., Boykoff, M., Byass, P., Cai, W., Campbell-Lendrum, 

D., Capstick, S., Chambers, J., Dalin, C., Daly, M., Dasandi, N., Davies, M., Drummond, P., Dubrow, R., Ebi, 
K. L., Eckelman, M., Ekins, P., Escobar, L. E., Fernandez Montoya, L., Georgeson, L., Graham, H., Haggar, 
P., Hamilton, I., Hartinger, S., Hess, J., Kelman, I., Kiesewetter, G., Kjellstrom, T., Kniveton, D., Lemke, B., 
Liu, Y., Lott, M., Lowe, R., Sewe, M. O., Martinez-Urtaza, J., Maslin, M., McAllister, L., McGushin, A., Jankin 
Mikhaylov, S., Milner, J., Moradi-Lakeh, M., Morrissey, K., Murray, K., Munzert, S., Nilsson, M., Neville, T., 
Oreszczyn, T., Owfi, F., Pearman, O., Pencheon, D., Phung, D., Pye, S., Quinn, R., Rabbaniha, M., Robinson, 
E., Rocklöv, J., Semenza, J. C., Sherman, J., Shumake-Guillemot, J., Tabatabaei, M., Taylor, J., Trinanes, J., 
Wilkinson, P., Costello, A., Gong, P., & Montgomery, H. (2019). The 2019 report of The Lancet Countdown on 
Health and Climate Change: Ensuring that the health of a child born today is not defined by a changing climate. 
Lancet, 394, 1836–1878. DOI: https://doi.org/10.1016/S0140-6736(19)32596-6

WHO. (1948). Preamble to the Constitution of WHO as adopted by the International Health Conference, New York, 19 
June–22 July 1946; signed on 22 July 1946 by the representatives of 61 states (Official Records of WHO no. 2, p. 100). 
World Health Organization (WHO).

https://doi.org/10.1016/j.enbuild.2012.12.033
https://doi.org/10.1016/j.enbuild.2012.12.033
https://doi.org/10.1016/j.enpol.2014.12.002
https://doi.org/10.1093/acprof:oso/9780199286294.001.0001
https://doi.org/10.1080/14649880500120491
https://doi.org/10.1080/14649880500120491
https://doi.org/10.1177/0021934706296188
https://doi.org/10.1016/S0140-6736(09)61716-5
https://doi.org/10.1089/env.2018.0041
https://doi.org/10.1016/j.scitotenv.2019.135038
https://doi.org/10.1177/0143624415621028
https://doi.org/10.1016/j.enbuild.2019.05.014
https://doi.org/10.1016/j.enpol.2019.111042
https://doi.org/10.1080/17565529.2013.828583
https://doi.org/10.5379/urbani-izziv-en-2018-29-supplement-005
https://doi.org/10.5379/urbani-izziv-en-2018-29-supplement-005
https://doi.org/10.1891/9780826190123.ap02
https://doi.org/10.1016/j.enpol.2011.11.093
https://doi.org/10.1016/j.envint.2015.09.010
https://doi.org/10.1016/j.envint.2015.09.010
https://doi.org/10.1016/j.enpol.2012.01.044
https://doi.org/10.1016/j.jclepro.2018.08.314
https://doi.org/10.1016/S0140-6736(19)32596-6


Climate justice and the built environment428

Whyte, K. (2020). Too late for indigenous climate justice: Ecological and relational tipping points. WIREs Climate 
Change, 11, e603. DOI: https://doi.org/10.1002/wcc.603

Wilkinson, P., Smith, K. R., Davies, M., Adair, H., Armstrong, B. G., Barrett, M., Bruce, N., Haines, A., Hamilton, I., 
Oreszczyn, T., Ridley, I., Tonne, C., & Chalabi, Z. (2009). Public health benefits of strategies to reduce greenhouse-
gas emissions: Household energy. Lancet, 374, 1917–1929. DOI: https://doi.org/10.1016/S0140-6736(09)61713-X

Willers, S. M., Jonker, M. F., Klok, L., Keuken, M. P., Odink, J., van den Elshout, S., Sabel, C. E., Mackenbach, J. 
P., & Burdorf, A. (2016). High resolution exposure modelling of heat and air pollution and the impact on mortality. 
Environment International, 89–90, 102–109. DOI: https://doi.org/10.1016/j.envint.2016.01.013

Wilson, B., & Chakraborty, A. (2013). The environmental impacts of sprawl: Emergent themes from the past decade 
of planning research. Sustainability, 5, 3302–3327. DOI: https://doi.org/10.3390/su5083302

Wolch, J. R., Byrne, J., & Newell, J. P. (2014). Urban green space, public health, and environmental justice: The 
challenge of making cities ‘just green enough’. Landscape and Urban Planning, 125, 234–244. DOI: https://doi.
org/10.1016/j.landurbplan.2014.01.017

Woodcock, J., Edwards, P., Tonne, C., Armstrong, B. G., Ashiru, O., Banister, D., Beevers, S., Chalabi, Z., 
Chowdhury, Z., Cohen, A., Franco, O. H., Haines, A., Hickman, R., Lindsay, G., Mittal, I., Mohan, D., Tiwari, 
G., Woodward, A., & Roberts, I. (2009). Public health benefits of strategies to reduce greenhouse-gas emissions: 
urban land transport. Lancet, 374, 1930–1943. DOI: https://doi.org/10.1016/S0140-6736(09)61714-1

WRI. (2020). World greenhouse gas emissions: 2016. World Resource Institute. Retrieved May 6, 2020, from https://
www.wri.org/resources/data-visualizations/world-greenhouse-gas-emissions-2016

Ziervogel, G., Pelling, M., Cartwright, A., Chu, E., Deshpande, T., Harris, L., Hyams, K., Kaunda, J., Klaus, B., 
Michael, K., Pasquini, L., Pharoah, R., Rodina, L., Scott, D., & Zweig, P. (2017). Inserting rights and justice 
into urban resilience: A focus on everyday risk. Environment and Urbanization, 29, 123–138. DOI: https://doi.
org/10.1177/0956247816686905

How to cite this article: Klinsky, S., & Mavrogianni, A. (2020). Climate justice and the built environment. Buildings and Cities, 
1(1), pp. 412–428. DOI: https://doi.org/10.5334/bc.65

Submitted: 27 June 2020        Accepted: 28 June 2020       Published: 14 July 2020

Copyright: © 2020 The Author(s). This is an open-access article distributed under the terms of the Creative Commons Attribution 
4.0 International License (CC-BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the 
original author and source are credited. See http://creativecommons.org/licenses/by/4.0/.

Buildings and Cities is a peer-reviewed open access journal published by Ubiquity Press OPEN ACCESS 

https://doi.org/10.1002/wcc.603
https://doi.org/10.1016/S0140-6736(09)61713-X
https://doi.org/10.1016/j.envint.2016.01.013
https://doi.org/10.3390/su5083302
https://doi.org/10.1016/j.landurbplan.2014.01.017
https://doi.org/10.1016/j.landurbplan.2014.01.017
https://doi.org/10.1016/S0140-6736(09)61714-1
https://www.wri.org/resources/data-visualizations/world-greenhouse-gas-emissions-2016
https://www.wri.org/resources/data-visualizations/world-greenhouse-gas-emissions-2016
https://doi.org/10.1177/0956247816686905
https://doi.org/10.1177/0956247816686905
https://doi.org/10.5334/bc.65
http://creativecommons.org/licenses/by/4.0/

	1. Introduction
	2. Dimensions of climate injustice
	3. The built environment and climate injustice
	3.1. Long timeframes
	3.2. Embedded accumulation
	3.3. Wellbeing and built environment synergies

	4. A capabilities approach
	5. Multivalent justice
	6. Contributions to knowledge of this special issue
	7. Current challenges for the built environment
	7.1. Governance and advocacy
	7.2. Documentation and analysis
	7.3. Training and capacity-building

	Acknowledgements
	Competing interests
	References
	Table 1
	Table 2
	Table 3
	Table 4