Beyond the new normal for sustainability: transformative operations and supply chain management for negative emissions

Stelvia V. Matos (Centre for Social Innovation Management, Surrey Business School, University of Surrey, Guildford, UK)

Martin C. Schleper (Information Systems, Supply Chain Management and Decision Support Department, NEOMA Business School, Reims, France)

Jeremy K. Hall (SPRU, University of Sussex Business School, University of Sussex, Brighton, UK)

Chad M. Baum (Department of Business Development and Technology, School of Business and Social Sciences, Aarhus University, Aarhus, Denmark)

Sean Low (Department of Business Development and Technology, School of Business and Social Sciences, Aarhus University, Aarhus, Denmark)

Benjamin K. Sovacool (Department of Business Development and Technology, School of Business and Social Sciences, Aarhus University, Aarhus, Denmark) (SPRU, University of Sussex Business School, University of Sussex, Brighton, UK)

International Journal of Operations & Production Management

ISSN: 0144-3577

Article publication date: 26 August 2024

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Abstract

Purpose

This paper aims to explore three operations and supply chain management (OSCM) approaches for meeting the 2 °C targets to counteract climate change: adaptation (adjusting to climatic impacts); mitigation (innovating towards low-carbon practices); and carbon-removing negative emissions technologies (NETs). We suggest that adaptation nor mitigation may be enough to meet the current climate targets, thus calling for NETs, resulting in the following question: How can operations and supply chains be reconceptualized for NETs?

Design/methodology/approach

We draw on the sustainable supply chain and transitions discourses along with interview data involving 125 experts gathered from a broad research project focused on geoengineering and NETs. We analyze three case studies of emerging NETs (biochar, direct air carbon capture and storage and ocean alkalinity enhancement), leading to propositions on the link between OSCM and NETs.

Findings

Although some NETs are promising, there remains considerable variance and uncertainty over supply chain configurations, efficacy, social acceptability and potential risks of unintended detrimental consequences. We introduce the concept of transformative OSCM, which encompasses policy interventions to foster the emergence of new technologies in industry sectors driven by social mandates but lack clear commercial incentives.

Originality/value

To the best of the authors’ knowledge, this paper is among the first that studies NETs from an OSCM perspective. It suggests a pathway toward new industry structures and policy support to effectively tackle climate change through carbon removal.

Keywords

Citation

Matos, S.V., Schleper, M.C., Hall, J.K., Baum, C.M., Low, S. and Sovacool, B.K. (2024), "Beyond the new normal for sustainability: transformative operations and supply chain management for negative emissions", International Journal of Operations & Production Management, Vol. 44 No. 13, pp. 263-295. https://doi.org/10.1108/IJOPM-06-2024-0487

Publisher

:

Emerald Publishing Limited

License

Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode

Introduction

The relationship between climate change and operations and supply chain management (OSCM) can be described as paradoxical: businesses are major causes of climate change, but will also be affected by, and necessary for, rectifying it. The 2,500 largest global corporations’ supply chains contribute more than 20% of global emissions (Gopalakrishnan et al., 2021) and eight of the world’s supply chains according to sectors (food, construction, fashion, fast-moving consumer goods, electronics, automotive, professional services and freight) account for more than half of all global greenhouse gas emissions (WEF, 2021). At the same time, modern supply chains are globally complex with significant upstream processes in regions vulnerable to climate change (Burke et al., 2015; Carleton and Hsiang, 2016). Hence, OSCM will be significantly affected by the upcoming costly cascading effects of climate change and emerging international regulations and policies (Ghadge et al., 2020; Holgado et al., 2024; Howard-Grenville et al., 2014). Conversely, reducing the world’s CO₂ emissions also offers industry huge opportunities (Bloomberg, 2020) – as much as $100tn (Carlin, 2021) over the next three decades, with annual investments exceeding $5tn. Therefore, any realistic effort to meet carbon neutrality and reduce climate change will require the expertise, resources and innovative capabilities of firms, and particularly OSCM (Helper et al., 2021), either via changes in operations and supply-chain network designs or diffusing technological solutions (Atasu et al., 2020).

Challenges however remain enormous. Although we now have consensus over the severity of the problem and a target of maintaining temperatures below 2 °C above the pre-industrial average, progress remains insufficient, thus making it “likely that warming will exceed 1.5 °C during the 21st century and make it harder to limit warming below 2 °C” (IPCC, 2023, p. 10). Consequently, the majority of the scientific community and the most recent International Panel on Climate Change (IPCC) report views carbon dioxide removal (CDR) as a necessary addition to a portfolio of climate strategies, which should be deployed in tandem with other mitigation methods (IPCC, 2023; Smith et al., 2024). CDR involves “all anthropogenic activities removing CO2 from the atmosphere and durably storing it in geological, terrestrial, or ocean reservoirs, or in products” (IPCC Intergovernmental Panel on Climate Change, 2019, p. 807) and is often envisioned through negative emissions technologies (NETs), which capture and safely store CO₂. A variety of such technologies exist, ranging from nature-based (e.g. afforestation) to engineering-based approaches (e.g. direct air capture and storage – DACCS) (Baum et al., 2023) [1].

According to Cobo et al. (2022), NETs are needed to meet the 1.5 °C target, given that up to 1,000 gigatons of CO₂ need to be removed by 2100. Compared with traditional climate strategies of mitigation that seek to halt climate change and adaptation that adjusts to future climate realities, NETs can potentially be deployed to slow and reverse climate change. In addition to governments, NETs are already being supported by a surprisingly large coalition of actors such as, for example, industry, scientists, civil society, farmers, fishers, financiers and insurers (Sovacool et al., 2024). Therefore, NETs present a vital fallback option if adaptation and mitigation prove inadequate.

Whereas techniques for adaptation and mitigation have been suggested in the OSCM literature (e.g. Bag et al., 2023; Ghadge et al., 2020; Nakano, 2021; Pankratz and Schiller, 2022), there remains a dearth of studies on how emerging NETs will be developed and diffused on larger scales through existing, or more likely new, OSCM mechanisms. Hence, this study seeks to answer the following research question: How can operations and supply chains be reconceptualized for NETs?

In what follows, we describe adaptation and mitigation through the lens of contemporary OSCM strategies and illustrate why they are necessary but not sufficient for rectifying climate change. We then describe our methodology, study approach and data analysis. Three NET case studies are presented through retrospective analysis of interview data and draw on two desperate discourses: from the OSCM literature, we utilize sustainable supply chain management (SSCM), and from innovation studies the sustainable transitions literature, to propose a third and complementary approach to adaptation and mitigation, which we call transformative OSCM.

While some emerging NETs show promise, there remains considerable uncertainty over supply chain configurations, governance, costs, efficacy, social acceptability and potential risks of unintended detrimental consequences (Augustine et al., 2019; Bloomberg, 2023; Harvey, 2023; Smith et al., 2024). The proposed concept of transformative OSCM complements contemporary sustainable OSCM thinking, which currently lacks adequate mechanisms to develop new technologies for emerging industry sectors driven by a social mandate but with elusive commercial incentives. It further emphasizes the need for policy intervention, a period of incubation for learning and a prioritization of ecological requirements over social and economic challenges. We concluded by exploring how OSCM can be reconceptualized to help rectify climate change through innovative NETs, thereby “moving towards a more desirable trajectory” (Davoudi et al., 2013, p. 311).

OSCM approaches to climate change

Two fundamental approaches that businesses usually employ to address climate change are adaptation and mitigation. According to the IPCC Intergovernmental Panel on Climate Change (2019, p. 804), adaptation refers to “the process of adjustment to actual or expected climate and its effects, in order to moderate harm or exploit beneficial opportunities.” Mitigation is defined as “a human intervention to reduce emissions or enhance the sinks of greenhouse gases” (IPCC Intergovernmental Panel on Climate Change, 2019, p. 819). In the following, we will introduce these two approaches from an OSCM perspective and link them to previously influential concepts, such as pollution control and pollution prevention. Table 1 provides an overview of the main concepts.

Adaptation: addressing the “new normal” with “old normal” OSCM practices

According to Atasu et al. (2020, p. 151), “adaptation for companies involves adjusting how they manage their supply chains, site their facilities, adjust their mix of products and services, and measure and report on their impacts in light of physical risks and regulatory changes related to climate change.” Negative repercussions from climate on operations and supply chains include abandoning production locations in regions exposed to floods, storms, draughts or heat waves (Easterling et al., 2000). Adaptation due to regulatory changes could for example include switching suppliers due to newly introduced CO2 limits in supply chains. How strongly these effects will materialize depends on the supply chain structure and which industry is considered, with sectors such as food being heavily impacted (Conway et al., 2015). Interestingly and unlike the general IPCC Intergovernmental Panel on Climate Change (2019) definition of adaptation, Atasu et al. (2020)’s definition considers only risks but neglects beneficial opportunities, such as shorter trade routes due to melted polar ice.

Originally CO₂ emissions were seen as a by-product but subsequently recognized as a climate change pollutant, forcing firms to adapt in response to risks and regulatory changes. Such an account of adaptation is far from new and has been discussed under the concept of “pollution control” since the 1990s (Florida, 1996). Pollution control involves technologies that treat or dispose of pollutants or harmful byproducts at the end of a manufacturing process to reduce the overall toxic content of environmental emissions and wastes (Florida, 1996; Gupta, 1995). Firms adjust existing practices in response to environmental impacts ex-post via technologies that typically come at the expense of other ex ante improvements (Florida, 1996).

We perceive adaptation as preparing operations and supply chains for uncertain and turbulent environments by adjusting to what has commonly been referred to as the “new normal,” albeit by utilizing the same pollution control approaches that ultimately minimize economic risks – i.e. embracing the “new normal” with tried and tested “old normal” practices. It thus reduces vulnerabilities by enhancing operations and supply chain resilience (Wieland et al., 2023) and resembles traditional supply chain risk management, i.e. making “decisions that optimally align organizational processes and decisions to exploit opportunities while simultaneously minimizing risk,” preventing supply chain disruptions and establishing resilience (Narasimhan and Talluri, 2009, p. 114).

Supply chain risk management can be either proactive or reactive, i.e. before or after a risk has materialized (Grötsch et al., 2013), with the former potentially being more cost-effective (Ng et al., 2018) but uncertain, whereas costs incurred by reactive approaches are typically passed on to consumers. For climate change, OSCM practitioners applying adaptation will navigate the actual and expected climate change repercussions and preempt regulatory changes by relocating supplier locations, establishing new processes or introducing modified or new products and services. For example, Ng et al.’s (2018) study on the Canadian port sector found that adaptation can reduce climate change impacts such as sea-level rise on shipping. However, insufficient collaboration among various stakeholders and the lack of incentive structures suitable for long-time horizons pose a major challenge to implementation (Madonna et al., 2024). Pankratz and Schiller (2022) find that buying firms are 6–11% more likely to cease supplier relationships and choose less risk-exposed ones when climate-related negative events exceed historical expectations.

From an uncertainty and risk perspective, a plethora of supply and demand side adaptation risks can be observed (Ghadge et al., 2020). Key issues with climate change include its influence on supply and raw materials and production processes (Alves et al., 2017; Kara et al., 2021), changes in demand and consumer behavior and regulatory uncertainty (Chen and Wang, 2016; Drake, 2018; Sunar and Plambeck, 2016). Ghadge et al. (2020) and Jira and Toffel (2013) suggest that most of these climate change risks on supply chains lack rigorous investigation.

In summary, adaptation is an inherently reactive approach to dealing with climate change by focusing on the economic viability and survivability of the firm by, for example, modifying supply chains in an attempt to return to normality (Wieland et al., 2023). However, while these responses to climate change are widely utilized in OSCM, they do little to rectify its root causes, resulting in “[…] a reductionist and static view on the supply chain and its management, promoting a global hunt for cheap labor and resources” (Wieland, 2021, p. 58).

OSCM mitigation: addressing the “new normal” with contemporary OSCM practices

Whereas adaptation focuses on reacting to actual and expected impacts of climate change, mitigation focuses on proactively lowering or eradicating emissions. For OSCM, mitigation is defined by Atasu et al. (2020, p. 151) as “developing new products, technologies, and services that support the transition to a low-carbon economy.” Hence, mitigation aligns with the established OSCM concept of pollution prevention (Geffen and Rothenberg, 2000; Klassen and Vachon, 2003) and “end of pipe” pollution control, where both approaches lower pollution, although through different means. The former has long been recognized as an advancement over pollution control by firms attempting to become more sustainable [2]. Both however still focus on “adjusting the existing system in response to an actual or expected change or disruption” (Wieland et al., 2023, p. 3), but otherwise continues the core business. Supply chain mitigation strategies thus mirror the shortcomings discussed in the SSCM literature (e.g. Montabon et al., 2016 Pagell and Shevchenko, 2014; Pagell and Wu, 2009; Sarkis, 2021). Indeed, progress toward sustainable supply chains has been described as modest (Gold and Schleper, 2017) or “slow, sporadic, myopic” and sometimes resulting in unsustainable practices (Sarkis, 2021, p. 65).

Drivers for supply chain mitigation include regulatory pressures to address climate change (Naumov et al., 2023), demand for green products (Ghadge et al., 2020), cost savings through emission reductions (i.e. eco-efficiency) or CO₂ tax anticipation (Dooley et al., 2019). Studies focusing on greenhouse gas emissions reduction often emphasize, if not prioritize, economic aspects (e.g. Plambeck, 2012; Saunders et al., 2020). Sartal et al. (2020) find a trade-off between decarbonization projects and firms’ labor productivity, which could jeopardize the former. An exception is Kagawa et al. (2015), who studied, from a macro-perspective, global CO₂ emission hotspots within more than 300 million supply networks. Given this non-firm-centric view, they provide an opportunity to detect and prioritize the largest emitters, allowing for more targeted mitigation efforts.

In addition to drivers, OSCM mitigation studies explore the role of emissions assessment (Alvarez et al., 2018; Rizet et al., 2012), the use of established practices such as supplier collaboration and information exchange (Dahlmann and Roehrich, 2019; De Stefano and Montes-Sancho, 2024; Jira and Toffel, 2013) and local sourcing and production (Nieuwenhuis et al., 2012), all of which have been found to reduce emissions. However, prior studies mostly focus on making unsustainable supply chains more sustainable, thus offering “limited insight into how to create an economically viable supply chain that at a minimum creates no harm and may even have positive or regenerative impacts on social and environmental systems” (Pagell and Shevchenko, 2014, p. 46).

Such deficiencies result from retrofitting established supply chains to become more sustainable by focusing on “synergistic and familiar” aspects, but neglecting trade-offs and radical innovation (Montabon et al., 2016; Pagell and Shevchenko, 2014). Synergistic in this context refers to the instrumental logic prioritizing economic supply chain performance over environmental and social parameters (Montabon et al., 2016). As Sarkis (2021, p. 65) states, firms tend to take the “road of least resistance focusing on win–win opportunities in meeting sustainability challenges,” where measures that fail to result in short-term economic benefits are discarded. “Familiar” relates to the tendency to enrich traditional OSCM research with sustainability perspectives, resulting in incremental progress (Pagell and Wu, 2009), as it retains the hegemony of economic profitability while addressing environmental and/or social issues. This familiarity is best expressed in the question “does it pay to be sustainable?”

In addition to most SSCM research being essentially incremental and focused on retrofitting, Bals and Tate (2018) also suggest that the design phase has been mostly neglected. A truly proactive approach would thus involve incorporating OSCM issues upstream in for example R&D and technology development phases (Wheelwright and Clark, 1992). This would involve difference forms of knowledge, such as competency enhancing (incremental) or destroying (radical), modular versus architectural innovation (Henderson and Clark, 1990), appropriability issues (Teece, 1987) and societal issues, which Hall and Martin (2005) and Matos and Hall (2007) have argued adds complexity and ambiguity to decision-making. Thus, like adaptation, mitigation will unlikely be enough to meet the Paris Accord targets (Financial Times, 2023), nor would they be sufficient to diffuse NETs.

Toward transformative OSCM

While adaptation and mitigation are necessary, many climate scientists argue that more drastic means are needed to meet the Paris Accord targets (Financial Times, 2023). For example, Minx et al. (2018) call for intentional efforts to remove greenhouse gases from the atmosphere through NETs. Given the potentially catastrophic and irreversible nature of the problem, they suggest that – counter to much of the OSCM discourse – it should be prioritized over social and economic parameters. Thus, if climate targets are to be met, entirely new industrial structures may be needed, or at least incumbent systems must be substantially retrofitted, areas which have until recently been underexplored. One such approach is “Transformative” OSCM strategies, defined by Wieland et al. (2023, p. 3) as an “ability to transform the system’s structures and processes more radically in response to changing conditions or disruptions”. Hence, we follow Ghadge et al.’s (2020, p. 59) call for “carbon supply chain management” (i.e. “designing and managing such unique supply chain networks for carbon capture, storage, transportation and usage”) and investigate NETs as a third and transformative approach to tackle climate change.

NETs capture and safely store CO2, thereby slowing down and potentially reversing climate change and regenerating social–ecological systems (Gualandris et al., 2024) in the likely event that adaptation and mitigation prove inadequate. However, research on these technologies is still in its infancy and its ultimate viability requires knowledge on the “socio-technical” perspectives in their deployment (Sovacool et al., 2023). Furthermore, NETs might be “facilitated or impeded through a variety of societal, political, economic, and resource-related factors” (Baum et al., 2023, p. 2). To fulfil their purpose, the supply chains and infrastructure also need to be demonstrably sustainable, where resource inputs, including carbon-neutral energy throughout the supply chain, do not negate the technologies’ carbon reduction efforts.

Given their novelty, NETs face poorly defined markets, infrastructure and partnerships, thus requiring radically new supply chain reconfigurations. A paradigmatic shift is thus needed, given its urgency and overshadowing implications. It thus corresponds to an “ecologically dominant logic” where social and economic parameters are nested within the environmental one as a prerequisite (Montabon et al., 2016). Consequently, we need to satisfy ecological requirements before we can turn to social and economic challenges (Griggs et al., 2013), which departs from the dominant contemporary sustainable OSCM thinking.

Building on these arguments, we thus postulate that research is needed that goes beyond SSCM to facilitate the development and distribution of NETs. As we will argue below, to do so we integrate SSCM insights with the sustainable transitions discourse, which explicitly addresses new policies for sustainable innovation, but so far offers only anecdotally limited empirical studies on how this can be operationalized through supply chains. Our argument is based on the premise that adaptation and mitigation can only reduce or eliminate CO₂ emissions, but that they are not intended to reduce global emissions. In contrast, NETs have no other (or limited) purpose other than to reduce global emissions and act as insurance in the likely event that mitigation will not be enough. As a result, the fundamental business model is very different, thus requiring new OSCM thinking.

Methodology

Research approach

Our approach to theoretical development follows similar OSCM studies dealing with novel contexts by combining the theoretical with the empirical to extend theory as abductive research (Ketokivi and Choi, 2014; Voss et al., 2015). As depicted in Figure 1, our theory elaboration process stemmed from a recursive dialogue between the theoretical (meaning) and empirical foundations (action), that led to the conceptual model of transformative OSCM at its center. The theoretical foundation provided by OSCM and SSCM studies helped us explain the need for considering the complex factors required for a low-carbon transition, and the transitions literature illuminated key aspects of transformative OSCM legitimacy. The empirical grounding of the research, on the other hand, focused on case studies to help unravelling the underlining mechanisms that shape the proposed transformative OSCM. In this process, theoretical reasoning was supported by empirical foundation, which in turn gained meaning through its integration with theory (Corley and Gioia, 2011).

Research on emerging NETs in the context of OSCM is complex because most are at early stages of development and/or implementation. This hinders access to data and restricts choices of methodological approaches, especially quantitative methods. To address this challenge, we follow other OSCM studies dealing with research constraints by looking retrospectively at data sources that would provide insights into the phenomena under investigation (DuHadway et al., 2022). More specifically, we used interview data involving 125 experts gathered from a broad research project on environmental, technical, social, legal, ethical and policy aspects of geoengineering and NETs (blinded to protect anonymity). We used this data to identify insights related to operations and supply chain issues, including related terms such as “value chain,” “suppliers” and “buyers” [3]. All interview data were triangulated with energy and policy studies to develop an initial understanding of the phenomena.

The original interview data collection involved open-ended questions used “to ‘open’ the talk and obtain ‘authentic’ accounts” (Rapley, 2001, p. 304). NET experts were identified from high-quality, peer-reviewed research publications or published patents, between 2011 and 2020 (Table 2). Interviews usually started by asking “What are the critical issues related to … ,“ “Who are the most important … ” and “What are the … .” Then non-inquisitorial questions would follow such as – “Why do you think that …, How do you work something …, This is interesting, why?” to invite interviewees to raise relevant issues within technological, commercial, organizational and societal dimensions of NETs (see Appendix for our interview guidelines). All interviews were conducted remotely in English, recorded and transcribed resulting in 130 h of data.

Interview data analysis and coding

Drawing on the “Gioia method” (Gioia et al., 2013), the initial stages of analysis (first order) involved a “rough” categorization of the data regarding technology development and OSCM issues. For example, the first order code “Can be facilitated via current OSCM practices” was created based on interviewee statements such as “What we propose is to replace some of these industrial fertilisers by slow-release fertilisers. Specifically, where the combination of the methods makes sense, like in the humid tropics, like in South America or in Africa. There, often, the farmers do not have the money for the expensive industrial fertilisers so there is the question: ‘what are alternatives?’. Slow-release fertilisers made out of minerals is what is coming into play” (R015). Another first order code “Needs to be built or repurposed from other industries (e.g. oil and gas)” resulted from quotes as:

Of course, there’s an enormous role for the oil and gas industry because they have all the skills and experience. I think there are four different direct air capture technologies. And all of them can be coupled with basically every kind of energy supply source (R094).

[…] What do you do with the CO2? So, you need to have it as close to sequestration sites as possible (R086).

Of course, if you are thinking about modularity, if you are going to have smaller plants, then you cannot really justify dedicated pipelines, can you? (R082).

A second-order analysis then looked for differences and similarities within and across the three selected technologies. For example, the first-order codes mentioned above “Can be facilitated via current OSCM practices” and “Needs to be built or repurposed from other industries (e.g. oil and gas)” were then refined into the second-order code “Infrastructure.” This process led to the identification of key themes: infrastructure, technological readiness, establishing legitimacy through learning, regulatory regime, policy incentives, business models, uncertainty, carbon accounting and reputation risk. Table 3–5 (further below) illustrate the data structure and provide illustrative quotes used during the analyses, which were then used as the basis of propositions and model development. Building on the example above, a detailed analysis of the many aspects related to the theme “Infrastructure” led us to conclude, among other things, that facilitating the development of NETs, requires OSCM to surpass incrementalism and establish the necessary infrastructure. The overall analysis process involved constant back-and-forth between the data, categories, concepts and literature, analyzing whether our findings were similar, contrasting or adding previous insights (Corbin and Strauss, 2015). To address internal validity, the authors regularly met to discuss each author’s coding, challenging one’s interpretation and codification of data until a consensus was reached.

Case sampling

The original qualitative dataset used in this study involved in total of 10 types of NETs: Carbon capture and utilization and storage, afforestation and reforestation, bioenergy with carbon capture and storage (BECCS), biochar, soil carbon sequestration or enrichment, ocean iron fertilization, ocean alkalinity enhancement (OAE), direct air carbon capture and storage (DACCS), enhanced rock weathering and ecosystem restoration. Using theoretical case sampling (Eisenhardt and Graebner, 2007), we selected three NETs: one biological or nature-based (i.e. biochar), one engineered or chemical (i.e. DACCS) and one ocean-based (i.e. OAE), IPCC, 2023). These technologies were the most frequently mentioned by the interviewees with regard to OSCM issues and could thus provide both depth and breadth of analysis, allowing us to capture as many OSCM issues as possible that either hinder or facilitate the adoption and diffusion of NETs. As per Table 6, the cases present different types of technology, degree of maturity, efficacy, potential applications, advantages and production cost estimates, providing a breath of differences and commonalities in maturity, scaling effects and infrastructure requirements. Such differences raise a diverse range of OSCM issues providing the opportunity to identify and analyze uncertainties over supply chain configurations, acceptability and potential risks of unintended consequences, thus illuminating underlining OSCM mechanisms for NETs.

Biochar

Biochar employs pyrolysis (i.e. chemical decomposition at elevated temperatures in an inert atmosphere) to convert organic material into a form of charcoal (i.e. biochar). By heating without oxygen, it is possible to obtain a stable, CO₂-rich solid. This offers a carbon sequestration method with relatively high efficiency that can endure for thousands of years when mixed with soil (Joseph et al., 2021; Lehmann et al., 2021).

Prior research found that biochar can facilitate soil amendment, enhance agricultural yield and improve soil and water quality (Kamau et al., 2019; Vijay et al., 2021). As a result, some recent field trials are exploring the carbon-sequestration potential and impacts on agricultural productivity of combined soil amendments of biochar and enhanced weathering (Bijma et al., 2021; Low et al., 2022). This results in primarily four objectives of biochar systems: reducing climate change, generating renewable energy, managing waste and soil improvement (Anderson et al., 2017).

Direct air carbon capture and storage (DACCS)

DACCS is an approach where mechanisms capture CO₂ from the atmosphere, compress it and safely store it in geological sinks or used to make long-lasting products like cement. Although featured in climate strategy since an IPCC (2007) report, it remains under-scaled. Distinct features of DACCS include two key aspects; the mechanism to capture the CO₂, and the infrastructure to store it, which in turn will determine their supply chain configuration and more generally efficacy and feasibility.

To capture CO₂, DACCS must first put ambient air in contact with a chemical reagent that removes the CO₂. Two chemical reagent systems are envisioned, with varying energy needs (Ozkan et al., 2022). The first includes various solid sorbents that require heating at 150C, which can hypothetically be powered by diverse energy sources, including renewables (solar, wind and geothermal) or waste heat from local grids (Madhu et al., 2021). The sorbents’ efficacies, however, vary depending on their locations; currently, humidity has a deleterious effect, so dryer climates are preferred. The second utilizes liquid solvents requiring process heating of 900C, which necessitates natural gas (Realff et al., 2021). DACCS systems relying on low temperature, solid sorbents can therefore leverage emerging (but still-unscaled) renewable energy but require high capital costs and technological improvements, whereas liquid sorbent systems require lower capital costs and can leverage existing fossil fuel and industrial systems albeit with lower net CO₂ captured.

Ocean alkalinity enhancement (OAE)

OAE or “enhanced weathering” employs alkaline materials (such as basalt or lime) which naturally interact with CO₂ to provide long-term sequestration of CO2 in the form of solid carbonate minerals. Limestone and basalt rocks wear from exposure to natural processes like rain, wind or waves, allowing them to absorb CO₂ from the air. However, this process is extremely slow, so enhanced weathering employs physical or chemical grinding of rocks before placing them onto land to expedite the process. Over time, the CO₂ can be stored in oceans indefinitely. Enhanced weathering is attracting growing attention for its potentially low-cost carbon-removal method on the magnitude of 2.9–8.5bn tons per year by 2100 (Beerling et al., 2020; Lehmann and Possinger, 2020).

Theoretical development

As discussed above, most of the SSCM discourse has been primarily focused on improving sustainability parameters while maintaining economic viability and thus provides useful insights for adaptation and mitigation. However, most focus on retrofitting existing infrastructures, with scant attention paid to the development of entirely new industries that support NETs. In this section, we develop a theoretical framework for transformative OSCM suitable for NETs that draws on the SSCM and innovation studies literature.

The diffusion of sustainable innovation via the supply chain has been discussed in the literature, starting with environmental innovation (e.g. Hall, 2000) and later focused on interactions amongst economic, societal and environmental parameters (Corbett and Klassen, 2006; Matos and Hall, 2007; Pagell and Wu, 2009). More recently, Kumar et al. (2020) and Costantini et al. (2017) suggest that environmental management in supply chains drives sustainable innovations, while eco-innovations are crucial for firms’ CO₂ emission reductions. However, implementation remains a challenge (Bals and Tate, 2018), especially “strong sustainability” (Sarkis, 2021) or “truly sustainable supply chains,” which “[…] at worst do no net harm to natural or social systems while still producing a profit over an extended period of time” (Pagell and Shevchenko (2014, p. 45). NETs however face poorly defined markets, infrastructure and partnerships, thus requiring radically new supply chain reconfigurations.

Such challenges of sustainable innovation have been examined by socio-technical transition studies as a transformative process involving technology management, user practices, policy, industrial networks and infrastructure (e.g. Geels, 2002, 2004; Geels et al., 2018; Weber and Rohracher, 2012). Transitions occur through processes of change in technological, material, organizational, institutional, political, economic and socio-cultural systems that lead to a complete (radical) or partial (incremental) replacement of the “old” with the “new” (Markard, 2011).

Energy supply is one type of socio-technical system, which involves interrelated networks of stakeholders (e.g. firms, government, consumers, NGOs), institutions (e.g. regulations, standards, incentives), materials (e.g. equipment, reagents, etc.) and knowledge (Geels, 2004; Markard et al., 2012). For example, Jacobsson and Bergek (2011) find that key weaknesses in supply chain diffusion among vertically connected firms include an inadequate technology base and lack of institutional support (e.g. R&D policies). Such difficulties are strongly related to coordination challenges when dealing with complementary firms and technologies in long supply chains.

According to the sustainable transitions literature, radical innovation usually requires an incubation period, where favorable market conditions and resource access incentives are available, allowing for experimentation and learning until adoption and diffusion hurdles are overcome (Geels, 2002). Building on Aldrich and Fiol (1994) and Hall et al. (2014) refer to this process as legitimization, specifically cognitive legitimacy, the knowledge that is needed to succeed in an industry, versus socio-political legitimacy, the value placed on it by cultural norms and political influences. They suggest that innovations establish legitimacy as technical performance and social acceptance co-evolve, allowing them to expand and reduce uncertainty. More recently, Hall et al. (2019) suggest that sustainability-focused new technologies typically lack cognitive legitimacy, specifically an economically viable business model. By leveraging socio-political legitimacy through, for example, demonstrating more sustainable products or services, the technology developers can justify longer term investment and time to establish cognitive legitimacy.

Previous research emphasizes the importance of defined business models for sustainable OSCM (Erhun et al., 2021; Van Wassenhove, 2018). Using the case of bioenergy from organic residues, Knight et al. (2015) identified pricing and availability of feedstock as key supply constraints in the technology adoption, which could be through collaborations among buyers and intermediaries. Drawing on a biochar supply chain analysis, Anderson et al. (2017) identify information management, resources and materials across the supply chain as key factors in moving this technology from a nascent to an established industry.

Combined, the above studies raise the need for effective guidance in dealing with the complex confluence of factors required for a low-carbon transition. However, according to the sustainability transitions view, OSCM for NETs must start with a clear prioritization of environmental criteria (i.e. carbon negativity) as the basis of the business model, otherwise, NETs would lack legitimacy. Consistent with Montabon et al. (2016) and Griggs et al. (2013), only then can other criteria, such as economic performance be incrementally addressed and eventually establish cognitive legitimacy through learning (Hall et al., 2014).

Regarding supply chains and network design, research focuses mainly on the economic optimization of physical flows, decisions about location, amount and capacity of facilities and supplier selection aspects using analytical modeling (see Meixell and Gargeya, 2005 for an overview). Accordingly, studies on sustainable and low-carbon supply chain design have also been approached through these methodologies (e.g. Eskandarpour et al., 2015; Gopalakrishnan et al., 2021). However, studies exploring how supply chains can be designed for sustainability transitions remain sparse. One exception includes Erhun et al. (2021) who reconceptualize Lee’s (2004) triple-A supply chain to propose a “sustainable triple-A supply chain” by incorporating sustainability in the definitions of agile, adaptable and aligned supply chains and achieved through radical innovation that focuses on sustainability in products/services, processes or infrastructure, restructuring existing supply networks or vertical integration. Similarly, Dooley et al.’s (2019) supply chain links to emissions study find empirical evidence that more modular process networks and those with higher commonality have lower production emissions than less modular ones.

In response, we propose to expand the SSCM literature by including insights from the sustainable transitions discourse, resulting in “transformative OSCM.” As we explore next, such an approach requires policy intervention, including new regulatory regimes and incentives that will provide the basis for business models. It also departs from mostly retrofitting changes, the focus of much of the OSCM discourse. Such transformative innovation usually requires a period of incubation, where favorable conditions such as market selection, access to resources and incentives are provided, allowing for experimentation and learning until adoption and diffusion hurdles are overcome. It may also depart from contemporary SSCM thinking, as transformative OSCM will need to prioritize ecological requirements over social and economic challenges, as the legitimacy of much of these technologies are based on their ability to rectify climate change, but otherwise offer no other value proposition. However, without them, we will be gambling on adaptation and mitigation technologies that will unlikely meet the Paris Accord targets.

Empirical foundation: illuminating the underlining OSCM mechanisms of NETs

Biochar

During the interviews, experts agreed that biochar can contribute to negative emissions immediately, given that some business models have already been implemented, such as fertilizers and veterinarian products or as a biofilter for gas and water filtration. Regarding infrastructure, biochar can benefit from the huge global volume, agricultural land and heavy use of fertilizers, which it could potentially replace. However, crucial considerations are the ability to demonstrate that biochar can enhance soil productivity and agricultural yield and moreover to do so competitively in various environments, with minimal transaction and implementation costs for farmers and land managers (cognitive legitimacy). This could be further catalyzed through policy interventions and clear regulatory frameworks resulting in wider biochar application adaptation in various sectors, such as agriculture or construction.

Another issue that arose is the infrastructure needed for the technology to reach scale. Although biochar as a soil amendment would require minimal changes for potential customers, suppliers of biochar are different from incumbent fossil-based fertilizer firms. Hence, such a substitution would probably necessitate a separate resource channel and supplier switching. Furthermore, short-term demand was identified, given that much of the required biomass is “already spoken for” (R019). Lastly, complementary innovators will need to be able to participate financially with the carbon-sequestration potential of biochar (and enhanced weathering), i.e. by obtaining carbon credits through monitor, report and verify frameworks.

Previous research (Low et al., 2022; UK Centre for Ecology and Hydrology, 2021) located biochar at various Technology Readiness Levels [4] between 5 and 6, given its different applications of which some are already in use. Biochar technology is based on substantial research, including a variety of laboratory experiments and field trials undertaken globally. Hence, biochar is not perceived as a radical technology but rather as a slow transition toward negative emissions in a “very low-tech manner” (R015; R019).

The presently limited knowledge of how the various layers of soils and their constituent organisms interact vis-à-vis the long-term sequestration of CO₂ represents an obstacle for commercializing biochar as a negative emissions technology and as such there are risks of potential unintended consequences. They are however mostly perceived as problematic for large-scale biochar applications, as indicated by R114: “I do think the problem is scale and the way it’s being done. I think, from our perspective, doing the type of biochar at a small scale […] has nothing to do with geoengineering.” In general, unintended consequences for biochar are relatively minor and uncomplex as they are usually spatially contained. Reputation risks associated with this technology and its applications are rare.

After more research on potential soil problems has been conducted, relatively straightforward application pathways could be imagined through learning and experimentation, increasing biochar’s cognitive legitimacy. For example, through a matrix that offers a “best-practice guide” that “says you have this climate, this soil, you want to grow this or that, then you have to apply that rock powder, that biochar to optimize the carbon storage in the plant and in the soil” (RO15). However, biochar solutions require sustainable OSCM practices, such as the use of clean energy and short transportation routes between production and application locations, otherwise, their negative emissions purpose would be significantly undermined.

For carbon accounting, mixed views were observed among the experts, regarding the ability to monitor, report and verify how much CO₂ is stored by biochar. Compared to the other two cases, biochar’s carbon accounting is relatively simple, however, adding a long-term perspective raises questions about the permanence of carbon storage by adding “huge uncertainty as to what is actually happening with carbon in the soils” (R039). In addition to encouraging new technological innovations, such a gap could also be addressed by engaging new partners in operations and supply chains. For example, ongoing trials undertaken by Project Carbdown (CDI, 2021) aim to investigate how much the combined application of enhanced weathering and biochar on agricultural fields can promote CO₂ removal and sequestration to generate carbon credits. This project thus departs from quintessential academic procedures by including specialist IT infrastructure-monitoring and a field service software management firm to develop low-cost devices to enable real-time “smart monitoring” of CO₂ removal.

DACCS

The supply chain and infrastructure for DACCS need to be carefully designed, both up and downstream. DACCS facilities are often cited for reduced spatial use and locational flexibility compared to other forms of carbon removal, although experts stated that this is misleading. Depending on the variant (solid versus liquid sorbent), DACCS infrastructure and upstream supply chains must navigate “co-location” between renewable or fossil fuel energy sources, water and other inputs, while transportation (pipelines and/or vehicles), storage sites (terrestrial or undersea formations) and diverse carbon-product facilities are also factors (Low et al., 2022). Solid sorbent DACCS could be located where renewables or waste heat are plentiful but unused, but perhaps at the expense of transport and storage. The range of co-locations that determine supply chains and capabilities is vast and currently immature and speculative.

From a downstream perspective, DACCS infrastructure needs to be built or repurposed from other industries such as petroleum, contingent on how the captured CO₂ is utilized. While biochar has direct use cases, DACCS’ output is storable CO₂, a perceived waste that needs sequestering in currently limited underground geological formations (e.g. basalt): “with the exception of North America, we’ve got […] physically [not] in place right now” (R077). However, experts also frequently referred to enhanced oil recovery (EOR) as a well-established business model and technical processes to use captured CO₂. EOR injects captured CO₂ into existing or depleted oil and gas fields to push out limited remnants, thereby lengthening its lifespan while sequestering CO₂. To date, EOR is the only industrial use of CO₂ reaching scalability. In the near term, EOR offers an opportunity to retrofit or shift the directionality of existing infrastructure, offering immediate learning and cost-reduction opportunities for sequestering CO₂ in fossil fuel reservoirs. Interviewees stated that it is thus currently the only viable business model and “there is no commercial benefit of any of these geological storage options if you exclude EOR” (R106). However, experts were also skeptical regarding EOR durability, given impending peaks in fossil fuel production and the paradox situation where:

[You] have paid the oil, gas, big energy companies trillions of dollars over the last couple of centuries to pull carbon out of the ground. You might pay the same companies trillions of dollars, through some carbon price scheme or some more direct incentive or through some kind of producer obligation, to put the stuff back in again. Of course, that, in a sense, is a paradox but it’s also not an unreasonable scenario given that they have the skills, geological scientific skills [and] the knowledge (R094).

Indirect business models for DACCS have been subsumed under the term carbon capture and utilization (CCUS) that include applications that use captured CO₂ in second-life products, such as construction materials, food and beverages production or synthetic fuels. Thus, captured CO₂ “can create a market, because it will be tied into utilization and that has a $1 trillion opportunity as a market – and that’s huge” (R052). However, DACCS is currently described as a technology that produces carbon waste with limited commercial viability, making it a “political market” (R106), meaning that regulatory frameworks and policy incentives are needed. Its success will thus be dependent on governance around future carbon pricing and accounting, with challenges over calculating life cycle emissions and gaps in monitoring, reporting and verification for carbon accreditation.

Low et al. (2022) and the UK Centre for Ecology and Hydrology (2021) located DACCS at Technology Readiness Levels 6–7. Besides EOR, DACCS illustrate technologies currently unproven at scale, except for some beacon applications by Climeworks in Iceland (Birnbaum, 2021). The current landscape sees a “new phase of direct air capture companies […] that are all about smaller modular and specific niche applications” (R052). Modularity options are perceived by many experts as key for learning processes, innovation and scaling: “modularity can happen within a large plant. So, if you modularize its components, then you have a modular supply chain and so you’re still getting that benefit of standardization” (R052). Others disagree, differentiating between capturing and storing, with the latter disadvantaged on scale economies when modularized. It further seems difficult to justify dedicated pipelines for smaller modularized facilities.

DACCS can thus be characterized as relying on a mix of established (EOR) and new science, where experts describe it as radical and potentially disruptive, especially if more solid sorbent innovation emerges. The costs of high- and low-temperature chemical reagents need to be reduced through scale economies. Interviewees stated that high-temperature solvents are more readily available from existing supply chains, whereas low-temperature solid sorbents require certain nanomaterials which “[…] don’t have supply chains yet. […] Someone must build [these]. The first thing you’d see if solid sorbents are going to win is you’ll see a Gigafactory equivalent of the supply chain to make those things” (R086). Solid sorbents also contain more cost uncertainties and therefore require dedicated rather than retrofitting existing production processes and supply chains.

During the interviews, potential unintended consequences for the technologies’ legitimacy were raised, such as “hazardous siting” (Hunold and Young, 1998) and “not in my back yard” (NIMBY). Pollutive industrial facilities have historically been located amongst marginalized communities (e.g. hazardous siting) with lower environmental, health and labor standards, and whose presence sometimes serves to depress standards through socioeconomic interdependence. Unintended consequences, such as carbon leakages from storage facilities are also a concern. In this context, the social acceptability and legitimacy of DACCS might be significantly low due to the NIMBY phenomenon, where concerns about health, pollution and social equity are subsumed with more general, even superficial concerns about the presence of any kind of change in an established culture and landscape. NIMBY could thus limit the storage location choice for DACCS, as “some regions have less easy access to geological potential for sequestration” (R014).

Regarding reputation risks, experts reiterated that low-temperature, solid sorbent DACCS relies upon a scaled renewable energy economy that does not yet exist. Until then, there will be trade-offs rather than synergies between DACCS and other energy needs, which could undermine the technology’s legitimacy. Moreover, experts frequently highlighted the reputation risks of being associated with fossil fuels through EOR, which “may kill [DACCS] companies, or may hurt them significantly” (R082). Conversely, experts emphasize that EOR offers policy opportunities for transitioning local communities dependent on the petroleum sector. If DACCS prolongs fossil fuel infrastructures in such communities, their gradual retirement might allow workers to transition from carbon extraction to sequestration, mitigating societal inequities while maintaining social cohesion and creating business opportunities.

OAE

Currently, OAE infrastructure is lacking, but a major advantage is that the technology offers almost unlimited CO₂ storage potential. Unlike terrestrial enhanced weathering cases, no related supply chains exist, which leads some experts to speculate that OAE will be “more of a local to regional operation if it can get to that scale, and not a global solution” (R060). Another stated: “to have an impact you would build up an industry like the global coal industry. So, you would move a lot of stones and I do not think that’s so realistic” (R008). One potential solution to scale up OAE infrastructure and logistics was mentioned by R015 and colleagues, who alluded to the possibility of “ships which have the minerals and maybe also a CO2 source on board. […] Because we have so many ships travelling, they can release, always, a little bit [mineral products for OAE] while travelling,” which however was skeptically considered due to the “need [for] the entire world shipping fleet to ship the stuff around” (R060).

Like DACCS, there are currently no clear business models for OAE and indeed might be more difficult to imagine, according to the experts. One major difference with DACCS is that OAE does not allow for CCUS. OAE-removed CO₂ is stored in oceans, making utilization difficult. However, two currently hypothetical business models were discussed. The first alluded to the generally “dirty” shipping industry and that “to make ships CO2 neutral, if you take 5–10% of the volume of a large ship […] you can store the mineral products, lime, and you have a reactor. Then you can use the CO2 from the engine and then you neutralize it. The CO2 will be transferred into alkalinity [which] […] helps to take up more CO2 from the atmosphere. So, you could, in theory, make ships CO2 neutral” (R015). Others mentioned how the dredging industry might “open up a whole market” for carbon removal that avoids the land-use conflicts, along with being “well-positioned to actually become a seller as well as a developer of these carbon-negative projects,” with some dredging companies already looking into this option (R080). This might be an upcoming development, given that “the naval sector has been kept out of the Kyoto and Paris accords”; “but the IMO, the International Maritime Organization of the UN has already said that [they] need to have [their] game in order, […] so, the naval sector is scrambling now to come up with interesting ideas” (R080).

Nevertheless, besides these to unrealized business models, OAE presents a “political market” like DACCS reliant on policy incentives and regulatory frameworks, such as carbon taxation: “Nobody is going to pay you to do ocean alkalization right now, so, if there’s not a carbon tax or some company isn’t willing to pay to remove their legacy CO2” (R036).

Another important factor is that OAE technology is currently unproven, difficult to test in situ and draws on relatively new science. Thus, consistent with our experts, previous research characterized OAE at TRL3 (Low et al., 2022), versus terrestrial counterparts, which is classified at TRL5 given the stronger evidence regarding benefits and risks, e.g. in agricultural soils. Accordingly, “there’s still an innovation gap there that really needs to be filled” (R036), and ongoing experiments and field trials are needing to run the gamut of research, development and deployment activities, with current projects simultaneously undertaking laboratory toxicity experiments, weathering process modelling and real-world field trials. This is best reflected by the multi-stage “project roadmap” put forward by Project Vesta (https://www.vesta.earth), a prominent OAE project.

Given these technological uncertainties, experts indicated that OAE probably faces significant unintended consequences: “When you’re plonking enhanced rock dust down on the ground, you know where you’ve put it, and it pretty much stays there. When you’re doing that in the ocean, there’s no telling where that’s going to end up” (R037). Experts emphasized that OAE is much more difficult to contain than land-based technologies, given the oceans’ fluidity, calling for international regulation “because you’re adding something in the ocean that’s not going to stay within your territorial waters, so there are cross-boundary effects” (R036).

Problems linked to limited in situ experimentation, potential detrimental unintended consequences and thus reduced learning opportunities lead to low cognitive and socio-political legitimacy as indicated by the experts:

It’s just not at the level of granularity where you feel comfortable to know what was happening and make an informed decision or be able to have an informed discussion with potential stakeholders around what the implications may be (R004).

What does the public want? People, I think, are very skeptical of dumping anything that seems like chemicals into the ocean, so I think that’s going to constrain it. We need a lot more experimentation – laboratory, and perhaps even some very small-scale field trials – before we can really start to get a handle on that (R060).

Reputation risks have thus been linked to the implementation of OAE, due to public opposition and the potential contradiction of the technology’s purpose without sustainable OSCM practices. Shipping and dredging industries are usually blamed for high net carbon emissions and high energy density. Moreover, the reliance on mining to provide vast amounts of basalt, lime and other rocks faces other sustainability issues, creating reputation risks. This multitude of risks and uncertainty is further exacerbated by highly complex and uncertain carbon accounting.

Table 7 summarizes our findings for each case and how they relate to our second-order themes, details of which will be discussed next.

Propositions: beyond the “new normal”

While a sense of urgency is emerging, there remain considerable challenges over how rectifying climate change can be operationalized, given the scale of the required investments and the need for global cooperation amongst a wide range of stakeholders. Currently, it remains uncertain how much it will cost to reverse climate change, and how it will be regulated and incentivized. As a result, the industry is still speculating on what business models may be suitable.

Table 8 summarizes the three approaches to how OSCM can respond to climate change. While contemporary approaches to incorporating sustainability in OSCM may be useful and necessary for adaptation and mitigation, it may not be sufficient for some emerging NETs. Given their novelty, some of these technologies will likely struggle due to poorly defined markets and lack of infrastructure and partnerships. As such, they will require radically new supply chain reconfigurations.

The relationship between climate change and OSCM is paradoxical. Past behavior contributed toward exacerbating climate change (Dooley et al., 2019; Gopalakrishnan et al., 2021) so there is a sense of culpability. Conversely, OSCM will be widely affected by climate change in terms of supply issues (Alves et al., 2017; Ghadge et al., 2020; Kara et al., 2021), demand, consumer behavior and regulatory uncertainty (Chen and Wang, 2016; Drake, 2018; Sunar and Plambeck, 2016). In response, firms will need to embark on adaptation strategies, allowing them to shift into the “new normal.” However, none of these practices are necessarily linked to sustainability but rather utilize proven generic OSCM techniques and strategies which contribute little to the implementation of true sustainability (Pagell and Shevchenko, 2014). Such a stance may maintain cognitive legitimacy but does nothing for socio-political legitimacy (Aldrich and Fiol, 1994; Hall et al., 2014, 2019), and thus the shadow of culpability remains.

Whereas adaptation is a reactive response to climate change, a more proactive response is mitigation. Although numerous studies emphasize mitigation in the OSCM literature, most are focused on reducing emissions assessment (Alvarez et al., 2018; Rizet et al., 2012), typically through established practices such as collaboration, engagement and supplier information exchange (Dahlmann and Roehrich, 2019; De Stefano and Montes-Sancho, 2024; Jira and Toffel, 2013) and local sourcing and production (Nieuwenhuis et al., 2012). All have been shown to reduce emissions and will be necessary but perhaps insufficient to reverse climate change, where firms face trade-offs between different sustainability dimensions, such as labor productivity and carbon neutrality (Sartal et al., 2020). Indeed, while mitigation clearly involves sustainability (Atasu et al., 2020), these improvements are mostly incremental and constrained by economic pressures. They thus reflect many of the shortcomings frequently criticized in the SSCM literature (Gold and Schleper, 2017; Montabon et al., 2016 Pagell and Shevchenko, 2014; Pagell and Wu, 2009; Sarkis, 2021).

One insight discussed from our study suggests that while adaptation can be achieved through traditional OSCM approaches, it does little to protect the firm from reputational damage and nothing to rectify climate change. Such a “business as usual for the new normal” (Wright and Nyberg, 2017) approach will undoubtably be under fire if other firms must carry the burden. Climate change thus sharpens the arguments extolling the virtues of adopting sustainable OSCM practices.

P1.

Traditional OSCM will have limited positive effects on stopping or reversing climate change, which will in turn damage the reputation of firms.

To facilitate the development of negative emissions technologies, OSCM must transcend incrementalism and establish the necessary infrastructure. We therefore propose the concept of transformative OSCM, which recognizes the need for policy interventions to address ambiguous commercial incentives, while simultaneously prioritizing the critical challenge of our era. Consequently, it underscores the need for novel OSCM infrastructure and business models as integral components of this transformative process. Unlike contemporary sustainable OSCM approaches, transformative OSCM recognizes the need for robust mechanisms to foster the emergence of new technologies in industry sectors driven by social mandates but lacking clear commercial incentives. We thus postulate:

P2.

Transformative OSCM, encompassing policy mechanisms and novel business models, will facilitate the development of negative emissions technologies.

A relatively new discourse calls for an understanding of the unanticipated outcomes of OSCM (Matos et al., 2020). We responded by showing that, given the need for more radical technologies and practices, transformational OSCM will likely create detrimental unanticipated outcomes if not managed carefully, although this is contingent on the nature of the technology (Harvey, 2023). For example, in our cases, biochar appears less likely to create unanticipated outcomes compared to the others. An important implication for decision-makers is that without careful management, NETs could lose their socio-political legitimacy long before a viable business model can be established, as most technologies’ main purpose is rectifying an environmental problem rather than exploiting an established and clearly defined market. Business models are already being developed, some of which may be questionable as they depend on collaboration among partially controversial stakeholders, such as petroleum companies for DACCS. Unintended consequences such as association with fossil fuels can significantly influence the creation of business models and the building of OSCM infrastructure, necessary for wide-spread adoption of these technologies, especially in the absence of more stable government incentives and regulatory frameworks:

P3.

Lack of policy incentives and regulatory frameworks can create a negative (unintended) impact on OSCM infrastructure for negative emissions technologies.

Lastly, counter to much of the sustainable OSCM literature that emphasizes the importance of balancing the triple bottom line, the significant complexity and distinctive features of emerging NETs require prioritization of environmental parameters, given that their legitimacy is solely based on rectifying a major environmental crisis. These findings further reiterate the perspective of an ecologically dominant logic, as advocated for by Montabon et al. (2016).

P4.

NET business models are solely dependent on tackling an environmental crisis and thus require an ecologically dominant logic that may unbalance triple bottom line approaches.

Contributions and conclusions

With the shift from polarized debate to implementation, scientific communities have identified a plethora of new technologies, techniques and policies for meeting emissions targets, but none will meet their potential without effective OSCM (Helper et al., 2021). In response, we identified how OSCM can be adjusted to meet CO₂ reduction targets, recognizing that adaptation and mitigation are necessary but unlikely sufficient. We contribute to theory by developing transformative OSCM as a mechanism that directly embraces the climate challenge through NETs. New policy mechanisms will be needed to regulate and incentivize the development of business models, which in turn will provide the infrastructure and supply chains necessary for such technologies to live up to their potential for stabilizing climate change.

Figure 2 summarizes our conceptualization of transformative OSCM. On the y-axis we distinguish how firms and their supply chains respond to climate change. It builds on seminal approaches to environmental management, i.e. whether reactive, proactive or core to the business model, as is the case for NETs. The x-axis represents the required degree of OSCM change, which ranges from retrofitting, to reconfiguring to entirely new restructuring. The size of the boxes represents the scale of the challenges, as well as the business opportunities that these challenges present.

Adaptation can be both reactive or proactive, but still uses traditional OSCM practices, where for example firms can retrofit in response to, or in anticipation of, climatic disruptions (Wieland et al., 2023). Such a response to climate change however does nothing to reduce CO₂ and thus is represented here in orange. Mitigation, represented here in light green, is more proactive, where the aim is to reconfigure OSCM practices with the ultimate aim of net zero (Atasu et al., 2020). However, the overarching value proposition of the firm remains the same and rectifying climate change is not core to the business. That is not to say that such approaches are obsolete – indeed, they are absolutely necessary but unlikely sufficient.

In contrast, transformative OSCM’s primary purpose is to reduce CO₂ and as a result, the response to climate change is core to the business. Building on Wieland (2021), transformative OSCM here applies insights from the transitions literature (Geels, 2002, 2004; Geels et al., 2018) that calls for policy interventions that foster incubation that allow for experimentation and learning, such as early favourable market conditions and resource access. It also draws on the technology and operations management literature (Hall et al., 2014; Matos and Hall, 2007) that emphasized the importance of legitimization processes to overcome complex hurdles and the unanticipated outcomes they may subsequently create (Matos et al., 2020).

Transformative OSCM may be radical (Henderson and Clark, 1990; Wieland et al., 2023), where new supply chains are forged, necessitating complex and resource-intensive alterations that can only become viable if the focus is shifted to environmental benefit. This phenomenon is for example evident in solid sorbents-based DACCS, where the integration of renewable energy sources requires the creation of new supply chains and industrial systems. Transformative OSCM innovation can also manifest via architectural innovation, where new OSCM approaches are required without significantly altering the individual components of the supply chain. Biochar, liquid-sorbent-based DACCS, and OAE are examples of technologies that utilize existing industrial systems but require a transition from prioritizing economic viability to emphasizing environmental benefits. These radical or architectural OSCM changes are difficult to identify and challenging to enact without the implementation of supportive policies.

Limitations and further research

This research was based on a preliminary study exploring new technologies for what has recently become a universally acknowledged crisis. As such, we acknowledge that our study has some inherent limitations and point out ways these can be addressed. The methodological challenges we encountered when researching early-stage technologies will diminish as NETs are further developed and implemented. Future research should leverage both qualitative and quantitative studies as new data becomes available to examine the nuances of transformative OSCM implementation, including addressing any unanticipated negative outcomes. Although data collected from the interviewees allowed for depth and breadth of analysis, other stakeholders who may be affected by the technology, such as farmers as users of biochar, are absent. Although we interviewed experts from 34 different disciplines, given the breath of the problem and the variety of potential technologies, data collection could include other stakeholders, as well as experts from related disciplines such as environmental law and political science. Future research should address these broader perspectives, which may raise other relevant issues and unintended consequences of NETs. A further limitation is the context under which issues identified in the data may (or may not) manifest. These could include, for example, socio-economic, geographical and temporal contexts, cultural, values and norms in different parts of the Globe and how these could hinder to promote of transformative OSCM. For example, future research could investigate the supportive policies needed to facilitate transformative OSCM in complex contexts, such as the Global South, which often operates under weak institutions and corruption.

A perhaps controversial but important area for further OSCM research is whether attempts to balance the needs and demands of the many have resulted in the state of procrastination and lethargy in addressing such an important problem. Counter to much of the discourse (including our own previous studies), the significant complexity, scale and urgency of the climate crisis requires prioritization of the environmental parameter. Additionally, most emerging NETs have limited utility without a strong focus on the environmental parameters, thus requiring focusing efforts in this area. It is thus worth exploring in greater detail how transformative OSCM may align with this prioritization, the requisite capabilities and the potential incumbency resistance such efforts may face. Such issues may sound daunting, but reinforce the need, and importance, for further OSCM research.

Lastly, all carbon removal technologies are linked to an ongoing debate on mitigation deterrence, or the moral hazard, in which the promise of eventual carbon removal creates systemic disincentives to undertake costly, substantial emissions reductions in OSCM. A broad assessment of unanticipated outcomes is thus an important area for future research. As noted by Nelson and Winter (1982), innovation resolves some problems but also creates new ones that must also be addressed. Past innovators, some of which pioneered the technologies that have contributed towards the climate crisis, could perhaps be judged as not responsible through ignorance, given that climate science was not understood. However, today we no longer have this excuse, and as such we have an obligation to search for how our efforts may result in detrimental outcomes and ways in which they can be avoided. Previous research has attempted to address this concern by bringing together technology developers with those responsible for commercialization, organizational issues and societal impacts at the early stages of the innovation process (Hall et al., 2014, 2019; Hall and Martin, 2005). Such an approach can explore how diverse secondary stakeholders may affect or be affected by NETs, as well as the impacts it could potentially have on the environment.

Figures

Figure 1

Overview of theory elaboration process

Figure 2

Conceptual model of OSCM approaches to the climate crisis

Table 1

Labels and concepts related to climate change rectification according to climate change and OSCM literatures

	IPCC literature	OSCM literature
Adaptation	“The process of adjustment to actual or expected climate and its effects, in order to moderate harm or exploit beneficial opportunities. In natural systems, the process of adjustment to actual climate and its effects; human intervention may facilitate adjustment to expected climate and its effects” (IPCC Intergovernmental Panel on Climate Change, 2019, p. 804)	“Adaptation for companies involves adjusting how they manage their supply chains, site their facilities, adjust their mix of products and services and measure and report on their impacts in light of physical risks and regulatory changes related to climate change” (Atasu et al., 2020, p. 151)
Mitigation	“A human intervention to reduce emissions or enhance the sinks of greenhouse gases” (IPCC Intergovernmental Panel on Climate Change, 2019, p. 819)	“Mitigation engages the innovation pathway and involves developing new products, technologies and services that support the transition to a low-carbon economy” (Atasu et al., 2020, p. 151)
Pollution control		Typically technologies that treat or dispose of pollutants or harmful by-products at the end of a manufacturing process to reduce the overall toxic content of environmental emissions and wastes. Control technology typically comes at the expense of other manufacturing improvements (e.g. pollution prevention) (Florida, 1996)
Pollution prevention		Changes in operations and supply chains that lead to less polluting or non-polluting products and processes (Florida, 1996)
NETs	“An activity or mechanism that results in negative emissions through removal of greenhouse gases (GHGs) from the atmosphere by deliberate human activities, i.e. in addition to the removal that would occur via natural carbon cycle processes” (IPCC, p. 819)
Carbon supply chain management		“Designing and managing [ …] unique supply chain networks for carbon capture, storage, transportation and usage” (Ghadge et al., 2020, p. 59)
Transformative supply chain management		“The ability to transform structures and processes more radically in response to changing conditions or disruptions” (p. 3). New supply chains are created based on new set of suppliers’ configuration and information exchange; and some supply chains might be displaced or disrupted (Wieland et al., 2023)