Digital home working and its sustainability potential: human immobility and the mobilities of stuff

Despite the huge human and economic costs of the COVID pandemic, many commentators have observed that this disruption – or shock – to our resource-intensive daily lives could offer a catalyst for the great societal transformations necessary to meet the climate emergency.

Radical growth of home working is an oft-cited example. According to Office for National Statistics (ONS) figures 50% of those in employment did some work from home in April 2020. This mainstreaming of home working has been facilitated by the rapid appropriation of digital devices and services into our everyday lives. It has been accompanied by equally rapid development of cultural skills and competencies required to (collectively) use those devices and services in a satisfactory way. And has led to major adjustments in how we work but also how we shop, interact, use our homes, engage with our local communities, learn, care for others and so on.

Home working during the pandemic, March 2020 (image: Simon Evans on Flickr)

The question is whether these shifts could lead to systemic environmental gains. Is it an environmental ‘good’ or ‘bad’? As ever with academics, our answer is ‘it’s not straightforward…’, but when viewed from a systemic perspective it does offer an opportunity to re-imagine sustainable ways of life.

When considering the environmental impacts of any technology or practice, understanding will be shaped by the scope of the analysis: what is considered inside the system being studied and what is ignored. A narrow scope, focused only on the technological parts of the system, makes it more straightforward to quantify the results (such as a ‘carbon footprint’ of something) but means missing out the broader implications – such as how any technology interacts with diverse social practices. One approach to this problem is to consider different scopes for analysis that address the direct, indirect and systemic impacts of a technology. We apply this framing to home working to consider some possibilities.

Direct impacts are the environmental costs of constructing, using and disposing of a technology. Engineering methods, such as life cycle assessment (LCA) (or more colloquially, ‘carbon footprinting’) can be used to model the technology’s life cycle, systematically collect the relevant data and then apportion the ‘environmental burden’ to the different applications of that technology. In the case of digital home working, this will include the impacts of manufacturing the equipment used and providing the electricity to keep it operational: both the home laptops and Wi-Fi, but also a share of the networking equipment used to connect workers with their offices and each other, and the data centres used to power the applications they use. Accounting for this ‘hidden materiality’, and the large consumption of energy used by data centres, has led to some fearing that the impacts of digital home working are substantial. Applying University of Bristol models developed for digital services to video conferencing suggests that the truth is somewhere between the two. A ballpark estimate for the climate impact of a one-hour video conference, for example, would be about 50-100g CO2e depending on the setup used – roughly equivalent to driving 400-800m in a typical family car. This suggests that we should not let concerns about the direct environmental impact of digital services put us off a move to home working.

Indirect impacts are the environmental costs of changing social practices related to the digital service. What do people stop doing? What do they start doing? Again, LCA can be used to quantify these – but only if one understands the nature of these changes. Social science insights are essential here, both to identify what changes to practice might occur, and to collect the data to quantify the extent to which they change across diverse populations.

In the case of home working, the most obvious changes to practice are reduction in travel to work and decreases in energy use within workplaces. These two factors will potentially be substantially larger than the direct impacts of technology use – but will be more variable and harder to predict across the population. Reductions in heating and lighting in the workplace were, it would appear, largely offset by rises of domestic energy use (Hook et al., 2020). The most dramatic potential environmental savings are from the sharp reduction in commuting, with the Department for Transport reporting a 60% reduction in private car usage during 2020 and a 90% decline in the use of public transport. But even here we must consider a range of related indirect effects of the apparent immobility of people. During the same period, we witnessed a huge increase in online shopping as people ordered their goods for home delivery. The ONS shows that online retail sales increased from just under 19% of total retail sales in November 2019 to almost 40% within a year. Groceries, clothing, household products and takeaway foods saw the largest growth.

The digital devices and services that allowed us to adapt so quickly to conditions of apparent human immobility also offered the technological affordances and cultural skills necessary for a commensurate growth in the circulation of goods, ordered online and delivered (often as individual items) to the homes of the immobile. Measuring these effects – especially if trying to capture the relative weighting of a trip to the shopping mall to purchase multiple items versus delivery of multiple individual items purchased online – would be necessary to estimate indirect impacts.

Systemic impacts consist of a huge range of elements that shape, and are shaped by, technologies and social practices. In the case of home working, we pick out three core elements: infrastructures, cultures, and modes of provision. To consider the impact and potential of home working we need to recognise the changing home to include the re-purposing of space for home offices and the technologies required, from the high tech (digital devices and networks) to the low tech (desks and storage). Local communities are also changing, and development of local service infrastructures to support mass home working (for example, the re-invention of the local high street) together with a corresponding decline of city-based office infrastructures will be required if home working is to be viable over the longer term. Each of these changes come with their own direct and indirect environmental impacts.

Cultural shifts must also be considered. Workplace cultures of presenteeism, long working hours, the status of private offices, and daily meetings are all challenged by home-working regimes. In addition, the rising use of digital platforms shows signs of fostering modes of provision through informal networks (such as familial and community based) that have, in recent history, been marginalised by the dominance of market modes of provision. Community sharing initiatives (such as food box schemes, local delivery hubs, community stores) coupled with the accumulating practical challenges of privately owned goods (as symbolised by the increasing percentage of domestic space devoted to storing seldomly used consumer goods and the decreasing use of expensive private cars) have been argued to indicate a shift towards collaborative consumption: the rejection of privately owned goods in favour of sharing (Southerton and Warde, forthcoming). While the direct and indirect environmental impacts of such systemic shifts are unknown, the potential to reduce the material flows of goods and reduce the impacts of human mobility are clear.

Thinking in terms of the systemic implications of home working – symbolised by the immobility of people and rising mobility of goods during COVID – is more important than only measuring direct and indirect impacts. As things stand, we are moving in the direction of ‘hybrid’ working, presumably on the grounds of a ‘best of both worlds’ assumption. From a systems level perspective there is a huge risk that we end up with two systems: workplaces and home working. Whether this ends up being the worst of both worlds, layering new resource-efficient systems over old resource-intensive systems, will largely depend on whether debates regarding the post-COVID world takes the opportunity to re-imagine and re-configure the systemic impacts of technology and human practice on the environment (Geels et al., 2015).

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This blog is written by Chris Preist, Professor of Sustainability and Computer Systems at the University of Bristol. His research focuses on the environmental impact of digital technology and consumer electronic goods; and Dale Southerton, Professor in Sociology of Consumption and Organisation at the University of Bristol. He studies consumption, its role in organising everyday lives and its significance in processes of societal change.

Why we need to tackle the growing mountain of ‘digital waste’

Image credit Guinnog, Wikimedia Commons.

We are very aware of waste in our lives today, from the culture of recycling to the email signatures that urge us not to print them off. But as more and more aspects of life become reliant on digital technology, have we stopped to consider the new potential avenues of waste that are being generated? It’s not just about the energy and resources used by our devices – the services we run over the cloud can generate “digital waste” of their own.

Current approaches to reducing energy use focus on improving the hardware: better datacentre energy management, improved electronics that provide more processing power for less energy, and compression techniques that mean images, videos and other files use less bandwidth as they are transmitted across networks. Our research, rather than focusing on making individual system components more efficient, seeks to understand the impact of any particular digital service – one delivered via a website or through the internet – and re-designing the software involved to make better, more efficient use of the technology that supports it.

We also examine what aspects of a digital service actually provide value to the end user, as establishing where resources and effort are wasted – digital waste – reveals what can be cut out. For example, MP3 audio compression works by removing frequencies that are inaudible or less audible to the human ear – shrinking the size of the file for minimal loss of audible quality.

This is no small task. Estimates have put the technology sector’s global carbon footprint at roughly 2% of worldwide emissions – almost as much as that generated by aviation. But there is a big difference: IT is a more pervasive, and in some ways more democratic, technology. Perhaps 6% or so of the world’s population will fly in a given year, while around 40% have access to the internet at home. More than a billion people have Facebook accounts. Digital technology and the online services it provides are used by far more of us, and far more often.

It’s true that the IT industry has made significant efficiency gains over the years, far beyond those achieved by most other sectors: for the same amount of energy, computers can carry out about 100 times as much work as ten years ago. But devices are cheaper, more powerful and more convenient than ever and they’re used by more of us, more of the time, for more services that are richer in content such as video streaming. And this means that overall energy consumption has risen, not fallen.

Some companies design their products and services with the environment in mind, whether that’s soap powder or a smartphone. This design for environment approach often incorporates a life-cycle assessment, which adds up the overall impact of a product – from resource extraction, to manufacture, use and final disposal – to get a complete picture of its environmental footprint. However, this approach is rare among businesses providing online digital services, although some make significant efforts to reduce the direct impact of their operations – Google’s datacentres harness renewable energy, for example.

It may seem like data costs nothing, but it how software is coded affects the energy electronics consumes. 3dkombinat/shutterstock.com

We were asked to understand the full life-cycle cost of a digital operation by Guardian News and Media, who wanted to include this in their annual sustainability report. We examined the impact of the computers in the datacentres, the networking equipment and transmission network, the mobile phone system, and the manufacture and running costs of the smartphones, laptops and other devices through which users receive the services the company provides.

In each case, we had to determine, through a combination of monitoring and calculation, what share of overall activity in each component should be allocated to the firm. As a result of this, Guardian News and Media became the first organisation to report the end-to-end carbon footprint of its digital services in its sustainability report.

But what design approaches can be used to reduce the impact of the digital services we use? It will vary. For a web search service such as Google, for example, most of the energy will be used in the datacentre, with only a small amount transmitted through the network. So the approach to design should focus on making the application’s software algorithms running in the datacentre as efficient as possible, while designing the user interaction so that it is simple and quick and avoids wasting time (and therefore energy) on smartphones or laptops.

On the other hand, a video streaming service such as BBC iPlayer or YouTube requires less work in the datacentre but uses the network and end-user’s device far more intensively. The environmental design approach here should involve a different strategy: make it easier for users to preview videos so they can avoid downloading content they don’t want; seek to avoid digital waste that stems from sending resource-intensive video when the user is only interested in the audio, and experiment with “nudge” approaches that provide lower resolution audio/video as the default.

With the explosive growth of digital services and the infrastructure needed to support them it’s essential that we take their environmental impact seriously and strive to reduce it wherever possible. This means designing the software foundations of the digital services we use with the environment in mind.
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This blog is written by University of Bristol Cabot Institute member Chris Preist, Reader in Sustainability and Computer Systems.

Chris Preist

This article was originally published on The Conversation. Read the original article.