The built environment has increasingly turned towards retrofitting as a means of reducing the carbon emissions associated with domestic heating and alleviating fuel poverty. Retrofitting, which in a built environment context usually involves the installation of insulation and technology to reduce carbon emissions, has gained significant attention in the last few decades because of its multiple benefits for people and planet. Despite this, there remains a critical omission within the discourse around retrofitting about its consequences for nature, in particular, the impact of retrofitting on the various species which make their homes in our homes or use them for nesting (i.e. various species of birds, incl. Swifts, House Sparrows and Starlings, bats, spiders, bees, toads and species of flowers and plants growing on and from walls). Many of these species are in rapid decline and need all the support we can muster. To date, the debate around retrofitting has focussed narrowly on the feasibility of different retrofitting solutions, optimising their performance and cost reduction as well as acceptability to end users. To neglect the impact on biodiversity is to ignore one of two existential threats faced by humanity: the parallel challenges of rapidly reducing carbon emissions and restoring biodiversity. Our survival rests on us rapidly meeting both these challenges and without awareness of the direct impacts on biodiversity associated with both the retrofitting of existing buildings and the construction of hermetically sealed new buildings, there is a risk that we exacerbate the depletion of the natural world in pursuit of carbon reduction. Solutions do exist that enable these two aims to be pursued in tandem, but awareness and adoption of them are too low and habitats within our homes continue to be destroyed at an alarming rate.
Retrofitting: not a neutral act
Buildings are responsible for 35% of all greenhouse gas emissions in the UK (23% residential and 12% non-residential) and given the nation’s ageing, inefficient building stock, retrofitting efforts and initiatives are required on mass to meet legally binding carbon reduction targets [1] [2]. The case for retrofitting the existing housing stock is further galvanised by high levels of fuel poverty across the UK, with over seven million households unable to heat their homes to a healthy temperature in England alone (National Energy Action, 2022). Better insulation has long been championed as a key means of alleviating fuel poverty and a pre-requisite to installing low carbon heat sources.
Examples of retrofitting within the built environment typically include insulation, low-carbon heat sources (photo voltaic panels, heat pumps etc.) and smart technologies. It can run along a spectrum from getting double glazing and fitting tighter fascia boards to passivhaus (with an air tight, highly insulated shell). Research on retrofitting has identified the various benefits these alterations and inclusions can bring about, including the reduction of energy consumption and energy bills, improved warmth and comfort and better cooling [3] [4]. Insulation is an important first step in preparing a property for the installation of low carbon technologies- ensuring the building envelope is as efficient as it can be, but it is also where the greatest harm to biodiversity is likely to occur.
However, discourses around retrofitting present few downsides aside from technical issues around ventilation and the potential for rising expectations around indoor temperatures amongst occupants (the rebound effect). As events such as Grenfell have shown however, the act of retrofitting is not neutral but instead, is tied to local politics and networks of power, often bound up with stakeholders whose motivations go beyond those of just sustainability [5]. As a now common occurrence within the built environment, critical research on retrofitting has begun to explore the wide variety of impacts it can have, beyond carbon reduction. Whilst research on retrofitting appeared initially confined to more scientific and technical studies, it has now expanded into the social sciences where qualitative work has unpicked many of its hidden dimensions. Despite this ongoing critical research, there appears minimal consideration of the impact of retrofit on nature and in particular, on the species which have evolved to rely on older, non-retrofitted buildings for survival. Indeed, the increasing influence of humans on the natural environment has, in some cases, robbed species of their traditional habitats, requiring them to find alternative habitats within the built environment where suitable alternatives exist. Many species have cohabited with humans for millennia (for example, Swifts). The insects and animals that live alongside us tend to rely on nooks and crannies within our buildings, which are sealed off when insulation is installed in pursuit of improved air tightness. For example, Swifts, House Sparrows and Starlings (all once abundant but now critically endangered species) rely primarily on gaps under the eaves of buildings to make nests and bats rely on access to roof space and narrow gaps in between bricks. Whilst nest boxes can be installed to support all of these species, they can often be poorly sited and unsuitable in various ways. Nest bricks tend to be more successful if correctly sited.
The neglect of biodiversity
Whilst researchers have examined the impact of retrofitting on human-nature relationships [6], these investigations have tended to centre on the environmental consequences of retrofitting technology production, as opposed to the impact of installation on biodiversity. Although research on retrofitting has noted the need to examine the practice from a wider range of angles, these calls have failed to identify a glaring omission around the impact on biodiversity [7]. There are a handful of research efforts which have explored the negative consequences of retrofitting on different species; however, these predominantly relate to large scale networked energy infrastructure [8] [9]. Despite being vital contributions towards understanding the consequences of retrofitting on species, these research efforts don’t address the knowledge gap around the impact of retrofitting at the building level. As retrofitting becomes increasingly common within the built environment and a vital tactic within carbon reduction policy and legislation, critical examination of its impact on species is urgently needed to prevent further damage to rapidly declining biodiversity.
Sustainability’s difficult questions
In their book Environmental Humanities (Humanidades Ambientales) [10], Albelda et al., (2018) note that within the paradigm of sustainability and associated research, there is an urgent need to ask more difficult and inconvenient questions. Sustainability needs to be considered in its broadest sense and we should resist a narrow focus on carbon reduction to the detriment of other equally critical aspects of sustainability, including a healthy natural world. The notion of ‘just transition’ has gained traction within sustainability discourses, noting that the vital shift towards a post-carbon society must be one that’s fair and equitable [11]. Research on just transitions has posed difficult questions around a range of topics, including the extraction of rare metals for low-carbon technologies [12] and employment within the fossil fuel industry [13]. However, consideration of non-human aspects of justice is still routinely overlooked in assessing the justice implications of sustainable transitions.
How can we help?
Nature doesn’t need us, but we need it and while we co-exist on this planet, we have a duty to support and protect biodiversity not only because we are part of an eco-system which relies on every species being healthy or that we rely on a functioning eco-system to provide us with food, but also because of the joy and wellbeing it brings us, especially in our darkest times [14]. Hearing sparrows chattering in the roof space above our heads can be an indelible childhood memory for older generations but is one that progressively fewer children are experiencing as they grow up detached from the natural world, adding nature deprivations to the list of other deprivations they may face as a result of the climate crisis. The simplest thing we as individuals can do for nature on a day-to-day basis is to allow it to thrive within our homes and gardens. And, although carbon reduction is also key to sustaining the natural world, we must consider the impact of decarbonisation on biodiversity and take advantage of the wealth of knowledge that exists amongst conservationists about how to accommodate nature within retrofit projects through things like specially designed, low-cost bricks, nest boxes and bowls and simple modifications to the building fabric. Everyone informing policy in this area and charged with implementing it, from researchers to government to installers and households needs to be aware of their impact on nature, the associated consequences and ways to avoid and mitigate damage. As researchers, we can provide the evidence base to support this, promoting critical examination of the full range of impacts associated with retrofitting but also linking up the currently disjointed debates about how to do retrofit, conservation adaptations and the huge benefits to humans resulting from proximity to nature.
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