Decay as a mode of biogas production: Digestive assemblages and value creation through microbial work

The circular economy and the microbial work of decay

In the EU, CE is currently seen as one of the main components of the transition toward “sustainable economic growth” (EU Commission, n.d.). Developing the operational environment of biogas plants is a central part of Finnish and Swedish national efforts for transitioning to a CE (see, e.g., Regeringskansliet, 2020; SOU 2019:63, 2019; Åkerman et al., 2020), especially through increasing the production of renewable energy and the circulation of nutrients through biogas production. The CE is opposed to the linear economic model of take–make–use–dispose, in which materials are exploited and then disposed of. Instead, the CE aims to “close the loops” by making materials circulate through reducing, reusing, and recycling (Ghisellini et al., 2016). The most optimistic promoters even highlight complete elimination of waste through the CE (Ellen McArthur Foundation, n.d.). However, CE as a model and ideology has also been critiqued from multiple different perspectives (see, e.g., Corvellec et al., 2022). Numerous scholars have, for example, pointed out that the slogan of waste to treasure is not as simple as it sounds but requires hands-on work, sensory practices, infrastructures, policies, and technology (Gille, 2010: 1054; Holmberg and Ideland, 2021; Lepawsky and McNabb, 2010; Lehtonen and Pyyhtinen, 2020). Along the way, the valuable gets turned into new trash that, in turn, gains new value in open-ended systems. Moreover, in practice, circular economies are packed with conflicts of goals. In biogas production, the ecological goal of recycling waste is at times not profitable, and infrastructures for biogas production demand a steady flow of new and more waste (Holmberg and Ideland, 2021). Moreover, biogas production is a CE solution that is largely based on technological solutionism and that “does not politically disrupt existing systems of environmental governance” (Koh, 2025: 1).

As stated previously, we problematize the idea of production in the context of the CE by focusing on decay as a productive, but also unruly, process of microbial work at biogas plants. According to dictionary definitions, the noun “decay” signifies rot and waste, and even death itself. It might be smelly, hazardous, or polluting. However, decay also refers to various things that get broken down and gradually move toward worthlessness. Typically, from a human perspective, the decomposition of biowaste in biogas facilities is framed as a passive or negative unilateral process of decay. Questioning this image, Ghassan Hage (2021) delves into the multiple meanings of decay, in particular its mortal figuration. For Hage, decay is, foremost, a liminal space as it signifies the not-yet-dead. Decay is the process of becoming dead or returning back to life. He thus puts the model to work in order to analyze social change. In a similar fashion, we investigate the process of biogas production through the lens of decay.

Biowaste cannot decay without microbes, which are particularly interesting multi-species workers. At biogas plants, microbes digest biowaste that is then converted into new products that ideally enter new economic cycles. However, regardless of their significance to the CE, microbes are not “big like us,” and thus they have for a long time passed under the radar of scholars in the humanities and social sciences (Hird, 2009). Bacteria have moved from being viewed solely as disease-generating enemies that need to be combatted to create and keep a healthy population, to being positioned as friendly allies that help human – and animal – bodies function (see e.g., Gröndal, 2018). Microbe/human ecosystems have even been elevated to a role model for how humans should be involved in ecological relations (Paxson and Helmreich, 2014). This shift in our way of relating to microbes has been conceptualized as “microbiopolitics” (Paxson, 2008), implying a kind of microbial workforce. The concept refers to the ways in which humans live with microbes and how human encounters with microbes are governed through different practices. The work that microbes perform may be viewed in terms of the domestication times/spaces of waste infrastructures. As specific kinds of waste infrastructures, biogas plants can also be seen as “more-than-human contact zones” (Haraway, 2008; Isaacs and Otruba, 2019), where humans and microbes encounter in particular ways. In the following section, we spell out how these encounters are crucial for value production in the context of the CE.

Digestive assemblages, encounter value and the marketization of biowaste and fertilizers

Although the work of microbes is crucial for the decay process, microbes alone cannot turn biowaste into valuable products at biogas plants. As mentioned above, to examine the decay process as a mode of production, we draw from the concept of digestive assemblage. Digestive assemblages are constituted by multiple, heterogeneous kinds of actors – waste infrastructure, plant workers, legislation, biowaste, and so on – that participate in the process in which waste decays. Assemblages often imply processes rather than a particular state as well as a decentering of human actors and human intentionality (Bennett, 2010). As we zoom in on microbes and decay activities, we follow the waste flows into the biogas plants and the ways in which these tiny actors assemble with others along the route. Biowaste (over)flows the world and mobilizes relations and microbes are indispensable to these assemblages of “waste-worlds” (Hird, 2016). The notion of digestive assemblage thus refers to the complex metabolic relations in which the excess produced by economic activities get digested, simultaneously creating new products and new kinds of excess.

To conceptualize microbial work along the digestive assemblage, we draw on the concept of encounter value (Barua, 2016). Simply put, encounter value refers to different kinds of values that are produced through and in the encounters between humans and animals. Building on Donna Haraway's (2008) concepts of encounter value and lively commodities, Maan Barua states that “encounter value can be thought of as that process of value generation where bodies, ethologies and liveliness of an animal makes a difference to, and is constitutive of, those very relations that render or mobilize it as a commodity” (Barua, 2016: 728).

So far, the concept of encounter value has mainly been used to study encounters between humans and mammals. These studies have analyzed the impacts of the liveliness of animals on the process of commodification (Barua, 2016; Pütz, 2021), among other things. For example, ecotourism and biodiversity conservation in India have been studied as settings in which humans can encounter “charismatic” (Lorimer, 2007) animals, such as lions and elephants (Barua, 2016). These encounters between nonhuman animals and humans create capital for those who harness the lives of such animals. Encounter value can also differ by context. In his study on the marketization of the American Mustang, Robert Pütz (2021) shows how encounter value is constituted through the situated encounters between individual humans and horses. In these encounters, Pütz highlights, affection and corporeal communication between the human and the horse are central.

Microbes are not charismatic in the same way lions or elephants are, and human–microbe relations are not always affective. However, in the context of biogas production, creating encounter value with microbes still requires being attuned to them and understanding what kind of effects different actions and waste batches may have on them. Thus, the production of value depends on the careful orchestration of encounters between humans and microbes. By focusing on encounter value production in the context of microbial work, we highlight how microbes are not simply a resource that humans can utilize to produce capitalist value; they can also be perceived as social actors that have the capacity to affect social, environmental, and economic relations. In our analysis, we utilize the concept of encounter value to examine how value production happens in different human–microbe encounters within the digestive assemblage.

The digestive assemblage is also connected to multiple different relations far beyond the biogas plants. This becomes especially apparent when we consider the fact that microbes do not only conduct the labor of breaking down the waste but are also central from the viewpoint of the marketization (Çalışkan and Callon, 2010) of the end products of the biogas production process. Following Koray Çalışkan and Michel Callon (2010), by marketization, we refer to the active practices of creating markets for things. Marketization involves sociotechnical assemblages that consist of the multiple human and more-than-human elements, such as rules, technologies, knowledge, and embodied competences, that are crucial to the formation of markets. As the environmental and economic value of biogas and fertilizers depends on the microbial decay processes, microbes participate in the marketization of these products. However, as we show in our analysis, the possibilities for the marketization of these products are also shaped by multiple other actors (see also Lehtokunnas and Pyyhtinen, 2023), which often complicates the process of creating economic value. Moreover, as our analyses illustrate, microbial work can also generate forms of production that hinder the process of marketization and even completely compromise human-centered understandings of value and economic production.

Biowaste

In this section, we analyze the orchestration of encounters between humans, different materials, and microbes in the first stage of decay at biogas plants – that is, the pretreatment process. At this stage, the pretreatment machinery in the plants crushes the biowaste and removes contaminants, such as packaging and metal, from it. The working of the pretreatment machinery is crucial for fostering the right kind of decay. This is because the material that arrives at the plants and that is treated under the title “biowaste” contains different materials that have very different liveliness and durability (see also Hawkins, 2023). It is rather fluid – in one of the plants, according to a waste trader interviewed, about a third consists of oil from grease separators. However, too much oil may disturb the microbes and hinder their work:

Grease separators are interesting, they are taken from food production, in industries and commercial kitchens and things like that- /…/And fat is good to rot, it will disappear, we rot it all away, but you can’t push too much because then it will, the bacteria don’t really like that. /…/ Then they get fat and then they don’t want to do anything. (Interview, April 2019)

In addition to the fact that the composition of the feed varies, biowaste is often packed in different kinds of wrapping: households usually pack their biowaste in biodegradable biowaste bags (and sometimes even in regular plastic bags), while the waste that comes from supermarkets and food industry businesses is packed in its original packaging. Moreover, sand often ends up among biowaste when biowaste bags are stored on the floor of biowaste reception halls at the plants. Microbes can work with the organic matter that biowaste contains (food scraps, peel, bones), but they cannot break down plastic, sand, and metal.

Machinery that removes packaging and other contaminants from biowaste is thus crucial for the plants. While the first author was shoveling dirt from the floor of the pretreatment hall together with the maintenance workers at one of the plants, they told her that the facility has very efficient plastic separation machinery that they have actively developed and enhanced over time. The plant machinery is constantly tinkered with when one gains knowledge and experience on the operation of the plant and the work of microbes. This illustrates how the digestion of biowaste at biogas plants cannot occur solely through the work of microbes; repair and maintenance practices are also crucial to the decay process. However, in addition that encounter value production requires repair and maintenance practices, the overflowing material that cannot be digested by microbes must be processed through alternative means, such as by transferring it to waste incineration plants. Thus, while plant workers and their repair practices are important parts of the digestive assemblage, the wider waste infrastructure is also crucial (Image 3).

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Image 3.

Analyzing plastic (Source: Tora Holmberg).

It is, however, quite common for the pretreatment machinery (especially the plastic separation one) of biogas plants to not work very well, and because of this, microplastics may end up in biogas reactors (Öling-Wärnå et al., 2023), resulting in the production of biogas decreasing due to there being less space for biowaste within the reactors. While it may seem obvious that removing contaminants—such as plastic packaging—from biowaste at the source would solve most of the problems, doing so would require significant additional effort from supermarket employees and other business staff. This added workload could lead to economic inefficiencies in their operations. These problems illustrate that while the digestive assemblage is connected to wider waste infrastructures, such as waste incineration plants, it also relies on the waste sorting practices of households and businesses before waste enters the biogas plants. Plastics among biowaste slurry thus show that practices that are considered “efficient” in one context can create indigestion and inefficiency elsewhere in the assemblage.

However, it is crucial to note that despite the problems related to plastics, most of the material arriving at the plants is still suitable from the perspective of microbial work. The microbes start their work of breaking down waste before the waste arrives at the plants. Because of this, the biowaste that is loaded into the biowaste reception and pretreatment hall is smelly and slimy, and the floors of biowaste pretreatment facilities are full of fluid that drains out from the biowaste bags. This goo needs to be constantly cleaned and washed from the floors – microbes are messy workers, and encounter value production requires human labor to clean up. Moreover, microbes not only produce the desired methane, but also other, dangerous, gases, namely, hydrogen sulfide. The plants need to monitor the amount of this gas in their facilities, especially in the biowaste pretreatment hall. When the first author was conducting fieldwork, one of the maintenance workers warned her about hydrogen sulfide while they were cleaning the floor of the pretreatment hall together:

The maintenance worker asked me if I knew the smell of hydrogen sulfide. I answered that I was not completely sure, and then the maintenance worker told me that it smells like rotten eggs. He told me that I should be cautious if I detect an odor like that. (Field diary entry, May 2021)

Moreover, the need to include and treat (almost) all kinds of biowaste once again illustrates how digestive assemblages are connected to the wider networks of waste economy. All biowaste that people produce needs to be treated in one way or another, regardless of the potential flaws it creates in the decay process. While in the context of the CE, biowaste has been turned into a resource for biogas production that the plants compete over, still all biowaste is not necessarily optimal material from a business model perspective. Considering the digestive assemblage, the understandings and goals related to efficient production may sometimes clash both with the reality of microbial work and imperatives related to treating waste in the most ecological and efficient way. In the next section, we further illuminate the practices of balancing between the productionist logic of biogas production and the unruliness and uncontrollability of microbial work.

Slurry

After the pretreatment process, biowaste has been crushed, squeezed, and liquidized into slurry – a wet, mucky, brownish substance. Being runny, it is moved through pipes into specific containers, in which its’ temperature is kept around 35–40 degrees Celsius. It is important to keep the temperature of the slurry suitable for the microbes to enable them to work as efficiently as possible. From the containers, the slurry is fed to the biogas reactors at a suitable pace. Inside the reactors, the microbes start their most important work – that is, the digestion of biowaste and gas production (Image 4).

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Image 4.

Biogas reactor (Source: Tora Holmberg).

In the facilities where the fieldwork was conducted, the slurry was kept inside the reactors for 21 days, after which the microbes have broken it down and the remaining digestate will be removed. The orchestration of microbial work in the digestive assemblage is reliant on practices such as adjusting temperatures and the rhythms of keeping the slurry inside the reactors. Through this calculation and management, the biogas production process is made as efficient as possible. However, there are certain obstacles that disrupt the efficiency of gas production. In addition to gas, the microbes may produce other kinds of matter, such as foam:

When we were sitting together and drinking coffee at the control room of the plant, one of the maintenance workers told me that he monitors the reactors from the computer screens next to us. According to him, the monitoring program shows how full the reactors are and if there is any foam inside the reactors. He said that in the worst case, the foam may get out from the reactor and spread around the plant area. (Field diary entry, May 2021)

In addition to highlighting the importance of feeding correct microbe groups, the plant workers often stressed how important it is to always keep the “portion” and the composition (degree of dry vs. wet substance) of feed steady to keep the working conditions of the microbes as steady as possible and prevent problems. This means keeping both the size and rhythm of feeding steady. All the talk about pace, rhythm, steering and portion implies industrial production and control. However, there are so many factors that can interfere with this, and no matter how meticulously the process is monitored and the feeding is tinkered with, full control cannot be accomplished. In the worst case, if the slurry is fed too intensively into the process, the microbes may die:

One of the maintenance workers told me that the whole biogas production process once stopped working completely in 2016. He showed me a figure that illustrated that the process fell down quite quickly, and the production of gas ended completely. The maintenance worker told me that one reason why the process ‘died’ was that biowaste was fed too intensively to the reactors. (Field diary entry, May 2021)

Foaming and other undesirable outcomes of microbial work shape the digestive assemblage in many ways. While many materials, such as sand and plastics, that end up at biogas plants may be considered excess from the viewpoint of microbial work, microbes themselves also produce many kinds of excess while they work. Thus, like all forms of value creation (see Greeson et al., 2020), the microbial work of biogas production also ends up creating different kinds of excess, such as foam and dangerous gases. This kind of excess is an unavoidable part of the digestive assemblage, and managing it is part of being attuned to the microbes and thus creating productive decay. For example, one of the plant workers explained that if he hears a buzzing sound coming from a pipe, he knows that foam is being created in the decay process and that he must take action to remove it before it causes problems. Thus, the repair and maintenance practices of the plant workers do not aim to create non-decay but rather to embrace and understand the process of decay (see Jackson, 2013) to make it as productive as possible while recognizing the impossibility of perfect industrial control.

Decay as a form of production thus requires constant balancing between the logic of the business operations of biogas plants (calculation, monitoring, management) and the unruly reality of microbial work. Biogas plants as digestive assemblages are connected to discursive and cultural understandings that relate to the logic of the CE. However, as this section has shown, the digestive assemblage does not only entail digestion, but it also paradoxically creates indigestion of materials, such as foaming of the reactors and inefficiencies in waste treatment practices. The findings illustrate how the reality of microbial work often clashes with anthropocentric understandings of efficient production.

Digestate and gas

In this section, we analyze what happens after the work of microbes within biogas reactors has ended and highlight the effect that microbes have “on the generation of value and on marketization processes” (Pütz, 2021: 587) of biogas and fertilizers. By marketization (Çalışkan and Callon, 2010) we refer to the ways in which the liveliness of microbes and the specific qualities of biogas and fertilizers shape the organization of markets for biogas and fertilizers.

After the slurry has been broken down by the microbes, gas production within the reactors ends. At this stage, the biowaste slurry has been turned into mass that is called “digestate,” which will be removed from the reactors. Here, it is important to take care that the microbes that may be hazardous for humans are removed so that the digestate can be safely used as fertilizer. To remove the unwanted microbes, the digestate is moved to sanitation tanks in which its temperature is increased to 70 degrees Celsius for a minimum. During the biogas production process, microbes are nursed to make their working conditions as good as possible, but after their work has ended, at least some of them (e.g., salmonella and e. coli) are destroyed. Although microbes are vital waste workers, consumer encounters with them must be controlled. This illustrates the dynamics of avoidance and care in encounter value production with microbes; hazardous bacteria are tolerated as waste workers, but when the products are moved to the markets and outside the more-than-human contact zone (Haraway, 2008; Isaacs and Otruba, 2019) of the biogas plant, their presence is no longer desirable.

After the digestate has been sanitized in a sanitation tank, it can be used as fertilizer, which is stored and distributed by the biogas plants. The fertilizers can be kept fluid, or they can be dried to allow different kinds of possibilities for use. The qualities of the dry and fluid fertilizers vary. They contain different amounts of nutrients, and different kinds are suitable for different plants and soil types.

The different wanted and unwanted materials that come to biogas plants with biowaste decay in different ways – the microbes will turn biowaste into digestate within 21 days or so, and this digestate is safe to be used as a fertilizer after sanitation. Microplastics, however, will not be broken down and thus they will be spread onto the fields. In this sense, the decay of biowaste and the different materials it contains continues even after the actual biogas production process at the plants has ended. Part of this decay is desirable, as plants and micro-organisms in the ground will benefit from the fertilizers. In this way, they are part of the digestive assemblage – after the fertilizer is moved out of the plant, the encounter value production continues in agriculture. However, decaying microplastics will clearly not create any added value in the fields. The end product of biogas production thus also contains material that is not valuable but rather is problematic waste; the circulation of nutrients comes together with the circulation of plastics. Thus, the indigestion that is created within this digestive assemblage is a problem both at the biogas plants and outside of them (Image 5).

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Image 5.

Different qualities of digestate (Source: Tora Holmberg).

In addition to the problems related to the indigestion of plastics, in many cases, selling the fertilizers does not produce a significant revenue stream for the plants (see also Lehtokunnas and Pyyhtinen, 2023). Farmers are often unwilling to pay for the fertilizers produced by biogas plants. Our informants reported many different potential reasons for this. Farmers may not, for example, be familiar to using the fertilizers produced by biogas plants, or they may not have suitable machinery for spreading it on their fields. Because of these issues, biogas facilities are often forced to give the fertilizers away for free and, in some cases, even pay the freight costs. When the first author asked the CEO of one of the biogas plants whether he considered the production of biogas or fertilizers more profitable for them, it became clear that fertilizers are in fact quite problematic for the plants:

The CEO said that fertilizers are a “necessary evil” for them, and they just try to somehow dispose of them. He said that at times it is hard to get rid of the fertilizers, and it is also difficult to obtain profit from them. (Field diary entry, June 2021)

Regardless of the difficulties of creating monetary value from fertilizers, our informants often strongly highlighted the importance of nutrient recycling. In fact, this was often a central part of the marketing practices of the biogas plants and thus also the marketization of both biogas and fertilizers. Moreover, practices such as giving the fertilizers away for free or paying the freight costs can also be seen as maintenance and repair that aims to embrace decay; the operations of the plants would be impossible if the end products were not moved forward in one way or another. Thus, this kind of maintenance is crucial for the metabolism of the CE, regardless of the economic inefficiencies it creates.

In addition to the fact that the fertilizers need to be moved forward in one way or another, even if doing so does not produce much revenue, the produced gas must, of course, also be distributed. Methane is a desirable component in the gas as it contains energy. The gas, however, also contains other, undesirable components, such as hydrogen sulfide, as we have already discussed earlier. Because of this, if the gas is used as traffic fuel, it must be purified. This means that the desirable methane must be separated from less desirable components (Image 6).

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Image 6.

Purification (Source: Tora Holmberg).

The gas can be used as traffic fuel, or in heating and electricity production. If the gas is used for heating or electricity production, it does not have to be purified. However, using biogas in heating or electricity production is not very profitable in some cases due to issues such as variation in demand (see also Lehtokunnas and Pyyhtinen, 2023). Further, the purification of biogas can be especially problematic for the plants:

If a biogas plant wants to build infrastructure that would enable the purification of the gas so that it would contain over 98 percent methane, that would mean that the plant should be able to invest at least one million euros in the machinery. But for example, for a biogas plant the same size as our plant, it would mean that you should be able to invest two million euros to be able to purify all the produced gas. And if you want to distribute the gas for traffic use, you will need to build a refueling station network. For building this kind of network, you will, again, need to invest at least one million euros. If we think about the number of cars that currently run on biogas, these kinds of investments are not justified in any way. (Interview, May 2021)

Because of the problems related to distributing the end products and creating monetary value for them, Finnish and Swedish biogas plants do not get their income mainly from selling the products they produce but from the “gate fees” their customers pay them for treating their biowaste (see also Lehtokunnas and Pyyhtinen, 2023; Åkerman et al., 2020; Winquist et al., 2019). Moreover, the challenges of efficiently circulating gas are part of the indigestion embedded in the operation of the assemblage. The difficulties of circulating the gas and fertilizers show that, in many cases, it remains unclear whether the process of decay produces valuable end products or problematic excess (see Lehtokunnas and Pyyhtinen, 2023). Thus, the marketization of biogas and fertilizers depends on the preferences of multiple actors within the assemblage, such as farmers and energy markets. In this sense, encounter value production involves not only the encounters between microbes and plant workers that enable productive decay but also many other elements that shape the process of value creation.

It is still crucial to note that regardless of these problems, most of the gas produced at biogas plants is utilized in one way or another: Only 11 percent of the gas produced at Finnish plants is torched (Suomen biokerto ja biokaasu ry, 2023), while at Swedish plants, only 8 percent is torched (Energigas Sverige, 2025). Still, considering all the problems related to creating monetary value from biogas, and especially from fertilizers, a question arises: Does it currently make sense to think about the marketization of biogas and fertilizers through the lens of economic value production, or are other forms of value currently more central in the case of creating encounter value through microbial work at biogas plants?

While biogas and fertilizers do not currently create steady income streams for biogas plants, there still exists a strong political aim to invest in biogas technology as part of the efforts of striving for a CE. As the biogas industry creates a certain kind of digestive assemblage that is strongly shaped by the CE discourses of turning waste into value and creating economic growth, the apparent difficulties of creating economic profit through producing biogas and fertilizers are somewhat paradoxical. Based on our analysis, we argue that rather than focusing only on economic value production in the sense of creating a steady revenue stream through the practices of turning waste into valuable products, it is crucial to also pay attention to the symbolic value that the work of microbes has from the viewpoint of the CE. While the CE is often associated with ideas such as creating an economy that mimics natural processes (Skene, 2018), the symbolic value produced through the process of decay and microbial work becomes central both from the viewpoint of the marketization of biogas and fertilizers and the digestive assemblage in which biowaste is treated.