Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-23T17:23:21.801Z Has data issue: false hasContentIssue false
  • English
  • Français

A multidimensional approach to knowledge coproduction in glaciology

Published online by Cambridge University Press:  19 November 2024

Marcela Brugnach Open the ORCID record for Marcela Brugnach [Opens in a new window] ,
Saria Sato-Bajracharya ,
Lisa Kranz ,
Nerea Bilbao-Barrenetxea  and
Sergio Henrique Faria Open the ORCID record for Sergio Henrique Faria [Opens in a new window]
Marcela Brugnach*
Affiliation:
Basque Centre for Climate Change (BC3), 48940 Leioa, Spain IKERBASQUE Basque Foundation for Science, 48009 Bilbao, Spain
Saria Sato-Bajracharya
Affiliation:
Faculty of Science and Technology and Research Centre for Experimental Marine Biology and Biotechnology PIE, University of the Basque Country, 48620 Plentzia, Spain
Lisa Kranz
Affiliation:
Basque Centre for Climate Change (BC3), 48940 Leioa, Spain
Nerea Bilbao-Barrenetxea
Affiliation:
Basque Centre for Climate Change (BC3), 48940 Leioa, Spain Faculty of Science and Technology, University of the Basque Country, 48940 Leioa, Spain
Sergio Henrique Faria
Affiliation:
Basque Centre for Climate Change (BC3), 48940 Leioa, Spain IKERBASQUE Basque Foundation for Science, 48009 Bilbao, Spain
*
Corresponding author: Marcela Brugnach; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

This work presents a reflection on the meaning and significance of knowledge coproduction in the field of glaciology. We start by invoking the paradigm of Structure–Form–Environment Interplay (SFEI) to formulate a generalised definition of glaciology, which highlights the relevance of knowledge coproduction. The adoption of a relational view of glaciological knowledge leads us to identify five core dimensions of knowledge coproduction: purpose, ethics, ambiguity, inclusion/exclusion, and relationships. Based on those dimensions, we delve into the decisive methodological aspects of the coproduction process, namely the definition of its purpose, the identification of participants, the organisation of the process, the recognition of ambiguity in Ways of Knowing (WoKs), and the consideration of ethical implications. In addition to the already known three stages of knowledge coproduction process (codesign, codevelopment, and codelivery), we propose the inclusion of an additional preparation stage, which entails the acknowledgment of the identity and involvement of all human and nonhuman participants, their positionality, and means to ensure their cultural and ontological safety. We reason that knowledge coproduction does not replace the scientific method, but rather complements it, eliciting the possibility to unveil deeper insights that might be difficult to attain through unilateral means.

Keywords

Ambiguitydecision-makingethicsinclusivenessindigenous knowledgelocal communityresearch responsibilitySFEIsustainabilityway of knowing
Type
Article
Information
Journal of Glaciology , First View , pp. 1 - 10
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of International Glaciological Society

Introduction

The interdisciplinary nature of glaciology makes it intimately related to the sciences of climate and the environment (Faria, Reference Faria2009; Laybourn-Parry and others, Reference Laybourn-Parry, Tranter and Hodson2012; Achermann, Reference Achermann2020), sharing with them the qualms and doubts about the potential social and environmental consequences of its research activities. Notwithstanding, drawing from its (geo-)physical roots, glaciological research has traditionally been performed with a positivistic perspective on exploration, deduction, and data collection, which identified the scientific method as the sole legitimate means of knowledge validation. While such an approach is undeniably powerful, it has recently been criticised for not recognising the fact that earth-science knowledge can no longer be regarded as just a neutral set of formal and systematic statements, such as hard and quantitative data (Sörlin, Reference Sörlin2009; Carey and others, Reference Carey, Jackson, Antonello and Rushing2016; Tadaki, Reference Tadaki2017; Burton, Reference Burton2022). Rather, it has evolved to be also relational (Bouwen, Reference Bouwen1998; Bouwen and Taillieu, Reference Bouwen and Taillieu2004; Brugnach and Ingram, Reference Brugnach, Ingram, Weber, Lach and Steel2017), in the sense that its production and significance depend on who is included in the problem-understanding process, how those included relate to each other to define the problem, and what type of knowledge is needed.

The relational aspects of knowledge just mentioned give rise to the concept of Ways of Knowing (WoKs), which is the process through which a problem or question is perceived, defined, assessed, and addressed (Feldman and others, Reference Feldman, Khademian, Ingram and Schneider2006; Lejano and Ingram, Reference Lejano and Ingram2009). The collective-interactive creation of knowledge by means of inclusion (who), relation (how), and validation (what) of diverse WoKs constitutes what is known as the process of knowledge coproduction (Bouwen and Taillieu, Reference Bouwen and Taillieu2004; Brugnach and Ingram, Reference Brugnach, Ingram, Weber, Lach and Steel2017).

The recognition that modern glaciological knowledge consists of both systematic (e.g. data-driven) and relational aspects, suggests that research and problem-solving in such contexts generally involves many WoKs, wherein knowing requires an understanding that is not only rational and cognitive, but also intersubjective and relational (Brugnach, Reference Brugnach2017). Evidently, the degree of WoKs diversity depends on the problem at hand, ranging from bare interdisciplinarity (e.g. first-principles study of proton disorder) to complex relational processes (e.g. glacier hydrology in populated areas). In general, however, the relational aspects of glaciological research are often underestimated. For instance, as will be discussed in more detail in the next sections, cryospheric research intrinsically has a strong relational component, due to its connections with the climate system, the environment, and human communities. Glaciers are more than just big masses of frozen water, they are perceived through an assemblage of relations that make them knowable and meaningful (de Landa, Reference De Landa2006). Nevertheless, many glaciologists still fail to recognise the relational component of their research, particularly in the most remote areas (e.g. Antarctica), with the misled argument that knowledge coproduction cannot transpire in an environment devoid of human communities and infrastructures.

In this work, we defend the thesis that a strictly detached approach to glaciological research may sometimes be incomplete, as it disregards the modern requirements of sustainable and actionable science. Scientific knowledge is deeply connected to societal influences and plays a fundamental role in shaping social order. As Jasanoff (Reference Jasanoff2004) argues, science and society are mutually constitutive: the creation and validation of scientific knowledge shape social structures, norms, and values, while the social and political context in which science is produced influences what kinds of knowledge are generated and accepted.

A more complete approach to glaciology shall integrate factual-scientific knowledge with other WoKs, through a process of coproduction that attends to plural perspectives practices, interests and aims while recognising the uncertainties, ambiguities, and contradictions involved in the process (Brugnach and others, Reference Brugnach, Craps and Dewulf2017; Lepenies and others, Reference Lepenies, Hüesker, Beck and Brugnach2018; Chambers and others, Reference Chambers2021). When properly performed, knowledge coproduction can provide a venue to gain a more democratic and comprehensive understanding of the cryosphere, and its relationship with people and the environment, and so serve to better achieve purposeful collective action.

Knowledge coproduction in glaciology

Defining the realm of glaciology is not a trivial task. Its interdisciplinary nature and ramifications into the physical, formal, and applied sciences, life and social sciences, and the humanities, make its boundaries diffuse (Faria, Reference Faria2023). The situation is aggravated by the persistent, popular misconception that glaciology were derived from the word ‘glacier’, implying that it would mean merely ‘the study of glaciers’. As pointed out by Seligman (Reference Seligman1961), the word ‘glaciology’ is actually derived from the Latin ‘glacies’, which means ice, and it ‘… has always been intended to cover every form of ice.’

Today, strong interactions and teleconnections between the cryosphere and various biotic and abiotic components of the earth system have been uncovered, revealing the transmission of signals and disturbances through the climate system, not only through physical and chemical processes but also through biological and societal pathways (Bravo and Rees, Reference Bravo and Rees2006; Hovelsrud and others, Reference Hovelsrud, Poppel, van Oort and Reist2011; Laybourn-Parry and others, Reference Laybourn-Parry, Tranter and Hodson2012; Bravo, Reference Bravo, Kowal and Radin2017). A simple way to summarise all those interactions and connections is through the paradigm of Structure–Form–Environment Interplay (SFEI; Faria and others, Reference Faria2009, Reference Faria, Kipfstuhl and Lambrecht2018) illustrated in Figure 1. The SFEI paradigm can be applied to a particular research topic or to glaciology as a whole. In the latter case, ‘Structure’ refers to the substance, ice of all kinds (i.e. snow, firn, ice, permafrost, etc.); ‘Form’ stands for all fashions of glaciological bodies and systems, either of natural origin (e.g. glaciers, ice sheets, sea-ice fields) or artificial (cold chains, freezing systems, etc.); ‘Environment’ denotes all types of surrounding features, like for example, natural and human systems.

Figure 1. Schematic representation of the Structure–Form–Environment Interplay (SFEI). The environment acts on form and structure; changes in form affect structure and environment; the structure influences form and environment.

The SFEI paradigm provides a logical generalisation of Seligman's (Reference Seligman1961) definition of glaciology as the study of all kinds of ice (Structure) in any fashion (Form) and considering all effects and consequences (Environment). It implies that a complete glaciological study entails coproduction, not only on the scientific level through an interdisciplinary approach (intrinsic to glaciology as a scientific discipline), but also through the integration of techno-scientific knowledge with other WoKs inherent to the Environment.

Such a generalisation of the definition of glaciology is essential to consolidate its relational nature over multiple scales, contexts, disciplines, and WoKs. A look at the glaciological literature reveals that the relational nature of glaciology harbours a huge research potential that has barely been explored yet. Indeed, most approaches to knowledge coproduction to date have tended to be topical and specialised, short-termed, or geographically localised:

  • In the context of high mountains and the Arctic, several studies have reviewed and examined the varying degrees of local participation and coproduction, and further developed frameworks to assist researchers, policymakers, and communities in moving towards the goal of coproduction (Robards and others, Reference Robards2018; Thompson and others, Reference Thompson, Lantz and Ban2020; Davis and others, Reference Davis2021; Yua and others, Reference Yua, Raymond-Yakoubian, Daniel and Behe2022). They concluded that coproduction attempts have often been limited to participation in data collection, thus being more consultative than collaborative. Failed attempts are usually characterised by merely adhering to protocols and funding criteria, resulting in tokenism (Davis and others, Reference Davis2021; Yua and others, Reference Yua, Raymond-Yakoubian, Daniel and Behe2022). Researchers rarely indicate how the local communities were involved in the research stages, including research planning, implementation, and evaluation of the research activities, as well as their share in power dynamics and governance. Several case studies of knowledge coproduction in Alaska have attributed their success to iterative and cyclic processes to define and resolve problems on a small location-based scale, and then eventually evolved to larger projects (Robards and others, Reference Robards2018). Another key element that was crucial for inclusive, equitable, and sustainable coproduction was placing emphasis on enacting Indigenous governance and sovereignty and ensuring continued access to culturally important resources (Thompson and others, Reference Thompson, Lantz and Ban2020; Hauser and others, Reference Hauser2021).

  • In the context of Antarctica and other global commons (i.e. Antarctica, the high oceans, the atmosphere, and outer space), the coproduction of glaciological and environmental knowledge has been significantly shaped through boundary organisations, which have played a decisive role in brokering knowledge between producers and users, including continued observation, deliberation and negotiation, which help develop a lasting trust and relationship among all parties (Elzinga, Reference Elzinga, Crawford, Shinn and Sörlin1993; Dodds and others, Reference Dodds, Hemmings and Roberts2017; López-Martínez, Reference López-Martínez, Oliva and Ruiz-Fernández2020). Furthermore, boundary organisations may also act as the very agents of coproduction, answering for the protection of such remote regions (Kennicutt and others, Reference Kennicutt2014; Hughes and others, Reference Hughes2018). That kind of coproduction is becoming increasingly important for Antarctic research, as the human activities in the southernmost continent (including research, tourism, and fishing) have grown dramatically in recent years, with powerful nations strategically positioning themselves to exploit weaknesses in the current Antarctic Treaty SystemFootnote 1 and the potential revision of several of its critical elements by 2048 (McGee and Liu, Reference McGee and Liu2019; World Ocean Review, Reference Gelpke2019, and references thereinFootnote 2).

The relational nature of glaciology unveils many direct and indirect interconnections, interactions, functions and consequences involving the cryosphere and its research. In particular, it invites glaciologists to reflect on their own research practices, roles and responsibilities, through the interconnections of glaciology with the social sciences and humanities on topics about, for example, research responsibility, sustainability, inclusiveness, and knowledge coproductionFootnote 3 (Bravo, Reference Bravo2009; Sörlin, Reference Sörlin2009; Carey and others, Reference Carey, Jackson, Antonello and Rushing2016; Dodds and others, Reference Dodds, Hemmings and Roberts2017; Radin and Kowal, Reference Radin and Kowal2017; de Pomereu, Reference de Pomereu2019; Burton, Reference Burton2022; Carey and Moulton, Reference Carey and Moulton2023; Robel and others, Reference Robel, Ultee, Ranganathan and Nash2024). Such studies shed light on the political, cultural, artistic, historical, philosophical, moral, and legal aspects of glaciological practices and glaciology itself. Accordingly, they deal with many questions related to coproduction in glaciology, like: Who responds for Antarctica? How to diagnose glaciological neo-colonialism? Is it legitimate to integrate glaciological local knowledge? Which measures can promote sustainability and inclusiveness in glaciological research? Finding answers to those and similar questions entails relating to multiple actors holding different WoKs. Some of them may have developed knowledge systems that, being different from the natural sciences, hold important practical or traditional wisdom embedding the experience of a long-lived connection to ice or related issues.

Coproduction of knowledge occurs by integrating all those WoKs into meaningful solutions that are useful, fair, and consensual. The integration is not straightforward, however, because the relational processes bear unavoidable uncertainties, ambiguities, and contradictions that must be identified and managed. In the next sections, we explore key concepts of knowledge coproduction, to gain deeper insight into the implications, drawbacks, and benefits associated with the generation of novel forms of glaciological knowledge through coproduction processes.

Dimensions of knowledge coproduction

The notion of knowledge coproduction is underpinned by the need to better link science and society in addressing issues or problems of common concern, producing blended forms of knowledge that are pertinent to the interests, values, and needs of those whose stakes are at play (Lepenies and others, Reference Lepenies, Hüesker, Beck and Brugnach2018; Beck and others, Reference Beck, Forsyth and Mahony2022; Büttner and others, Reference Büttner2023). While there are many ways in which the coproduction of knowledge has been conceptualised and practised (relevant reviews are Bremer and Meisch, Reference Bremer and Meisch2017; Brugnach, Reference Brugnach2017; Lepenies and others, Reference Lepenies, Hüesker, Beck and Brugnach2018; Miller and Wyborn, Reference Miller and Wyborn2020), generally it makes reference to the process of generating actionable knowledge forms by combining a plurality of knowledge sources and types (e.g. scientific, expert, local knowledge). Such a process is not meant to be limited to an intellectual exchange or interdisciplinary integration of neutral and objective scientific knowledge. Instead, it is intended as a space for the development of novel, relational forms of knowledge, research, and action that, without excluding objective science, permit connecting different existing WoKs and bodies of expertise and skills.

In practice, knowledge coproduction can be understood as an iterative process of the coordinated action of diverse actors (e.g. stakeholders, shareholders) who engage in some form of collaboration to create knowledge capable of addressing common collective problems (Brugnach and Özerol, Reference Brugnach and Özerol2019; Bandola-Gill and others, Reference Bandola-Gill, Arthur and Leng2022). A process of mutual understanding that is carried out via dynamic interactions among knowledge holders, who while working toward common objectives, exchange what they know and what they need through discourse and communication. Ample evidence suggests that through these collaborative processes, new ways of comprehending can be developed, broadening the boundaries of substantive knowledge, while at the same time providing knowledge that is more suited to actors' requirements and hence more likely to be employed (Lemos and others, Reference Lemos2018; Chambers and others, Reference Chambers2021; Howarth and others, Reference Howarth, Lane, Morse-Jones, Brooks and Viner2022).

When adopting a relational view of knowledge, there is no fixed recipe for how to carry out processes of knowledge coproduction. These are processes that are case-specific and contextually defined, and as such they can rarely be standardised. However, a growing body of research in coproduction indicates that coproduction must operate at two levels:

  1. (1) Substantive: referring to the content that is being created for the purpose sought.

  2. (2) Procedural: referring to the rules and organisation underlying the process of knowledge creation that bring about substance; and in doing so, to pay close attention to who gets to participate, under which conditions, towards what end, what relational practices support actors´ interactions, how differences and controversies are resolved (Caniglia and others, Reference Caniglia2023).

Next, we will look in more detail at the five core dimensions of knowledge coproduction (Fig. 2), how these processes can be applied, and how they may serve to advance what is known about ice.

Figure 2. Core dimensions of knowledge coproduction.

Knowledge coproduction is a process with a purpose

Coproduction processes can encompass diverse meanings and ends, underlying motives that are numerous and diverse (Lepenies and others, Reference Lepenies, Hüesker, Beck and Brugnach2018; Norström and others, Reference Norström2020; Maas and others, Reference Maas, Pauwelussen and Turnhout2022; Honeybun-Arnolda and others, Reference Honeybun-Arnolda, Mahony and Chilvers2024). The coproduction of public services, the codevelopment of knowledge to support decision-making, or the cocreation of solutions to common challenges, are a few common examples. The purpose of a coproduction process is what determines who gets to participate, what resources are needed, and how a process is organised. In glaciology, some frequent purposes of coproduction are the development of adaptation strategies for local communities, protection against cryospheric hazards, support of decision-making for governance, and improvement of sustainable and responsible research (Bravo, Reference Bravo2006; Hughes and others, Reference Hughes2018; Chown and Brooks, Reference Chown and Brooks2019; Abdel-Fattah and others, Reference Abdel-Fattah, Trainor, Hood, Hock and Kienholz2021).

Coproduction of adaptation strategies and protection against cryospheric hazards refers to the processes that are carried out at a regional scale with the objective of developing, jointly with various actors, forms of adaptation in the context of hazards related to cryospheric climate change. In mountain regions, not only are the cryospheric components such as ice, snow, and permafrost at direct risk of melting and disappearing (IPCC, 2019) but also the local communities who are dependent on these elements. While the vulnerability of these communities varies geographically and to different degrees, effects on water supply and economic dependence seem to be of particular importance. High-mountain communities and downstream users worldwide rely on the seasonal supply of water from melting snow and glaciers, and the impacts of climate change on these elements will consequently have effects on the water availability for drinking, irrigation, and hydroelectricity (Immerzeel and others, Reference Immerzeel2020; Lutz and others, Reference Lutz2022). Risks of glacier lake outburst floods (GLOFs) are also increasing (Harrison and others, Reference Harrison2018; Bazai and others, Reference Bazai2021). In the Alps and other European high mountains, the impacts of decreasing snow cover, melting glaciers, and increased risk of ice and rock avalanches are observed in the tourism sectors that depend heavily on winter and mountaineering activities (Bruley and others, Reference Bruley, Locatelli and Lavorel2021; Salim and others, Reference Salim, Ravanel, Bourdeau and Deline2021). With rapid changes occurring in the cryosphere, ecosystem services across the world are inevitably affected, which makes it imperative for different actors to create and implement effective adaptation plans (Moors and others, Reference Moors2011; Huggel and others, Reference Huggel2020; Drenkhan and others, Reference Drenkhan2023).

The objective of improving decision support for governance and for sustainable and responsible research is twofold: (i) to minimise the impacts of glaciological research activities upon natural environments and local communities (Hughes and others, Reference Hughes2018; Kettle and others, Reference Kettle2019), and (ii) to adapt the existing ecosystem and climate services surrounding glaciology to the specific needs and interests of local users (Bravo, Reference Bravo2006; Abdel-Fattah and others, Reference Abdel-Fattah, Trainor, Hood, Hock and Kienholz2021). Decision support tools encompass resources that help support decisions at different scales including information gathering, data analysis and modelling, and decision implementation (Bhargava and others, Reference Bhargava, Power and Sun2007). Such tools have historically utilised technological and analytical approaches but equally important are social communication, local observations, and voices that provide information beyond data and numbers (Cruikshank, Reference Cruikshank2005; Bravo, Reference Bravo2009; Sandré and others, Reference Sandré, Wardekker, Gherardi, Bremer and Wardekker2024).

For example, in the Alaskan Arctic, the development of collective decision support tools has been particularly important as vast resources and ecosystem services related to sea ice and wildlife are shared and used by many actors including traditional hunters, local communities, scientists, and offshore industry operators. Local communities and subsistence hunters have generations of experience and knowledge on their local conditions and environment that are useful for purposes such as understanding sea-ice safety for travel and expeditions (Albert, Reference Albert and Norton2000; Mahoney and others, Reference Mahoney, Eicken and Shapiro2007; Kettle and others, Reference Kettle2019), conservation of wildlife and protection of their habitat, risk, and benefit assessment for consumption of subsistence food (Moses and others, Reference Moses, Whiting, Bratton, Taylor and O'Hara2009; Babu, Reference Babu2023), and minimising offshore oil and gas as well as shipping traffic (Davis and others, Reference Davis2021).

Decision support to minimise the impacts of glaciological research activities is also crucial for inhabited regions. For instance, Antarctica is identified by international law as one of the four global commons (together with the High Seas, the Atmosphere, and Outer Space), defined as those parts of the planet that fall outside national jurisdictions and to which all nations have access (UNTT, 2013; Dodds and others, Reference Dodds, Hemmings and Roberts2017). As such, the Antarctic environment and its resources are protected by the principle of the common heritage of humankind (Joyner, Reference Joyner1986), which guides also the planning of Antarctic research and governance (see e.g. the scientific advice to the Antarctic Treaty System and the codes of conduct for scientists working in Antarctica provided by the Scientific Committee on Antarctic Research, SCAR: https://www.scar.org/).

Knowledge coproduction includes and excludes

The coproduction of knowledge involves creative processes that notably differ from the traditional production of scientific knowledge through the scientific method. Instead of having a main knowledge holder (i.e. a scientist) observing and describing an external reality, during a coproduction process, there are networks of actors holding diverse forms of knowledge, which come together to create yet new blended knowledge forms collectively. These actors define the issues of concern, determine what needs to be known and done to address them and identify the type of knowledge that needs to be developed. Attention should be given to the fact that the inclusion of certain actors inherently determines who is excluded.

In a coproduction process, actors are knowledge holders who can be involved in several different ways (Davis and others, Reference Davis2021). Considering involvement from the perspective of power, Arnstein (Reference Arnstein1969) distinguished between different roles, from nonparticipation (manipulation, treatment), tokenism (informing, consultation, placation), and citizen control as inclusive forms of self-mobilisation and auto-determination. Being aware of the type of actor engagement helps align individual and collective expectations regarding roles and responsibilities in the creation of the new knowledge, making the process more transparent and also asserting that the people who need to be involved are actually involved, so as to mobilise the knowledge that is needed.

In glaciology, the question of who produces glaciological knowledge, and how such knowledge is used or shared is not usually emphasised. Systems of domination and structures of power and patriarchy have long fed the production of glaciological knowledge (Bravo and Triscott, Reference Bravo and Triscott2011; Carey and Moulton, Reference Carey and Moulton2023; Robel and others, Reference Robel, Ultee, Ranganathan and Nash2024) and this has set the standard where the ‘who’ has predominantly been the Western scientists. Other forms of cryospheric knowledge, such as folk and grass-roots glaciology, which have been produced at different times and places by diverse peoples, cultures, and social groups (Cruikshank, Reference Cruikshank2005; Carey and others, Reference Carey, Jackson, Antonello and Rushing2016; Munir and others, Reference Munir, Bano, Adil and Khayyam2021), have remained marginalised. Here, we suggest that knowledge coproduction can provide an opportunity to decentralise this ‘who’, amplifying the voices and narratives of those whose glaciological knowledge has been systematically dismissed.

Knowledge coproduction builds on relationships

Coproduction processes that support the creation of new knowledge go in tandem with developing high-quality relationships among actors, based on mutual understanding and trust (Brugnach, Reference Brugnach2017; Fleming and others, Reference Fleming2023). That allows advocates for supportive dialogical settings, where mutual listening, debate, learning, and negotiation are encouraged, to communicate their expectations and presumptions. Through these exchanges, they collaborate to generate new blended knowledge forms. It also implies paying close attention to the interaction among knowledge holders, and the relationships of production and power underlying the exchange of knowledge among them.

Coproduction procedures must pay special attention to ‘what is going on’ while the actors are interacting. It is critical to take into account not only who is engaging and who is missing, but also what happens when different actors interact: how people communicate, what is said, and what is not said. It is conceivable for powerful individuals to impose their opinions in order to further their own agendas (Zingraff-Hamed and others, Reference Zingraff-Hamed2020). Well-performed coproduction processes must consider empowerment programs and operational and structural support instruments (such as legal aid, information access, and capacity building) that restore the balance of power among participants (Gerlak and others, Reference Gerlak2023). They also call for a continuing review of the participation rules (Brugnach and others, Reference Brugnach, Craps and Dewulf2017). In short, setting a coproduction process to work demands much more than merely bringing knowledge holders to a table: it requires the capacity for dialogue among knowledge holders, even when power asymmetries, identity issues, differential access, or control over resources or information is at play.

At a global scale, the IPCC provides a notable example. Until the IPCC's Fourth Assessment Report (AR4), Indigenous Peoples were largely overlooked as holders of valid knowledge, and their contributions were neglected (Ford and others, Reference Ford2016; Brugnach and others, Reference Brugnach, Craps and Dewulf2017; Mahony and Hulme, Reference Mahony and Hulme2018). Since then, the IPCC has made significant efforts to include Indigenous knowledge, however effectively integrating nonscientific perspectives with scientific literature remains a significant challenge (Chen and others, Reference Chen and Masson-Delmotte2021). Critics argue that the IPCC engagement with Indigenous knowledge frequently is superficial and tokenistic, prioritising scientific epistemologies, thereby perpetuating power dynamics that marginalise and sideline nonscientific knowledge forms, particularly those rooted in Indigenous traditions (Hernandez and others, Reference Hernandez, Meisner, Jacobs and Rabinowitz2022; Carmona and others, Reference Carmona2023; Rashidi, Reference Rashidi2024). These dynamics are further exacerbated by institutional structures, which often exclude Indigenous Peoples from meaningful participation (Asayama and others, Reference Asayama2023).

In knowledge coproduction ambiguity is unavoidable

Often hidden within assumptions, the coproduction of knowledge among multiple holders also entails handling ambiguity. Ambiguity arises when diverse WoKs are brought together, leading to confusion and differing interpretations within a group (Brugnach and Ingram, Reference Brugnach and Ingram2012). It reflects the differences in understanding among knowledge holders regarding a particular situation. Inherent in any coproduction process that involves diverse actor groups, ambiguity highlights that WoKs may not always align.

Ambiguity can manifest in various ways, pointing out discrepancies that may be substantive (such as differing views on the significance of a melting glacier), procedural (involving rules, formal agreements, regulations, or laws, such as measures to mitigate landslide, avalanche, and glacial-flooding risks), or process-related (concerning informal relationships, interactions, and participation, such as the roles played by scientists, boundary organisations, and local actors).

While ambiguity can be a valuable source of creativity and innovation, it can also lead to contradictions and even conflicts among knowledge holders, hindering the group's ability to work collaboratively toward a common goal. These differences may create confusion about the primary issues of concern, the relevant sources of knowledge, how to integrate different WoKs, or what actions need to be taken. In the process of coproducing knowledge, it is crucial to recognise and address these differences in a way that constructively harnesses the diversity of WoKs rather than diminishing it. In such contexts, dialogical forms of coproduction are particularly effective (see Brugnach and others, Reference Brugnach, Dewulf, Henricksen and van der Keur2011, for various strategies to navigate ambiguity).

When working in polar or high-mountain regions, ambiguity becomes also an inevitable consequence of knowledge coproduction between glaciologists and local communities, as those actors hold different WoKs, values, practices, and systems. As a result, discrepancies arise in the framing of the glaciological issue and its relevant solution, be it a loss of glacier mass from a geophysical perspective or the loss of a cultural monument and water resource through the eyes of local communities (Cruikshank, Reference Cruikshank2005; Bravo, Reference Bravo2009; Carey and Moulton, Reference Carey and Moulton2023). This ambiguity then has implications for the management, conservation, and adaptation plans, and often results in disagreements, misalignments, and tensions among people (Brugnach, Reference Brugnach2017).

Exemplary instances of ambiguities arise when the geophysical view of glaciologists is confronted with the cultural and symbolic values of glaciers for the local communities living near them (Orlove and others, Reference Orlove, Wiegandt, Luckman, Orlove, Wiegandt and Luckman2008). In the Canadian Arctic, for instance, Cruikshank (Reference Cruikshank2005) reports local narratives of sentient glaciers that become offended by the smells of cooking with grease, sometimes reacting with great danger, for example, through glacier surges. In the Karakoram, local understanding assigns genders to the glaciers, which can be combined through the Indigenous practice of glacier grafting to generate new ice (Gioli and others, Reference Gioli, Khan and Scheffran2014; Munir and others, Reference Munir, Bano, Adil and Khayyam2021). While climate change projections warn of drastic glacier retreats globally (IPCC, 2019), the current climatic anomaly in the Karakoram results in relative glacier stability (Hewitt, Reference Hewitt2005; Farinotti and others, Reference Farinotti, Immerzeel, de Kok, Quincey and Dehecq2020), which may spark peculiar expectations of glacier and hydrological security among the local people. Here, acknowledging and addressing ambiguities in knowledge and future climate projections become key issues in the adaptation to climate change. On the one hand, because their absence would rather entail that other forms of knowledge outside the dominant one have been dismissed or invalidated. On the other hand, because local knowledge forms can offer alternative venues for adaptation that are not foreseen with science alone.

Knowledge coproduction demands clear ethical boundaries

Creating blended knowledge that goes beyond scientific understanding and includes different WoKs raises ethical implications regarding the participatory processes underlying knowledge development and its substantial output, bringing up fundamental questions about property rights, knowledge sharing, and use. Several authors have argued that knowledge coproduction between scientific and nonscientific actors (e.g. local communities) can lead to the emergence of a participation paradox (Craps and others, Reference Craps, Dewulf, Mancero, Santos and Bouwen2004; Quaghebeur and others, Reference Quaghebeur, Masschelein and Nguyen2004); where local knowledge holders may find themselves excluded by the knowledge, structures, and procedures that are meant to involve them, reinforcing even more the relationships of power and the legitimisation of scientific knowledge (Brugnach and others, Reference Brugnach, Craps and Dewulf2017). Notably, there are issues concerning:

  1. (1) Self-determination: It raises questions regarding the process underlying coproduction, if, for example, it is voluntary and informed, and regarding the influence or authority granted to the nonscientific actors. In knowledge coproduction and collaborative partnership among different knowledge holders, there should be a consensual agreement on their ‘knowledge sharing process’. This requires ‘cultural safety’, an inclusive environment fostering a trusting and reciprocal working relationship with individuals from diverse cultural backgrounds (Bourassa and others, Reference Bourassa2020). When knowledge is sacred, this process becomes increasingly important as it is not necessarily sharable or accessible without special rituals or practices (Fung, Reference Fung2006; Brugnach and others, Reference Brugnach, Craps and Dewulf2017).

  2. (2) Property rights and transparency: Taking into account property rights and transparency involves examining the legitimacy of the representation of knowledge holders, questioning who is being credited for the coproduced knowledge and if the use of local knowledge forms is used with the proper consent of its legitimate owners. In climate-change-related projects, it is not uncommon a lack of transparency and accountability, and as a result, elite groups, including scientists, are able to capture the benefits, sometimes even to the prejudice of Indigenous communities (Turner and Clifton, Reference Turner and Clifton2009; Brugnach and others, Reference Brugnach, Craps and Dewulf2017; Klenk and others, Reference Klenk, Fiume, Meehan and Gibbes2017; Jull and others, Reference Jull, Morton-Ninomiya, Compton and Picard2018).

  3. (3) Knowledge appropriation: Issues of appropriation involve assessing whether nonscientific knowledge is appreciated in its entirely or fragmented into data to conform to the standards of Western science. It is important that the coproduction process does not discount and local and indigenous knowledge by treating them merely as an extractive source available for scientific research. The appropriation of local knowledge systems out of their original context to fit into the epistemological and ontological framework of Western science not only marginalises local WoKs, but also breaks the ties that bind local knowledge to their local interests, governance, and social practices (Smith and Sharp, Reference Smith and Sharp2012; Latulippe and Klenk, Reference Latulippe and Klenk2020).

In sum, in glaciology, as in any other complex multidisciplinary field, knowledge coproduction can be viewed as a process that connects different WoKs by bringing together the expertise and skills of a wide range of actors in ways that are fair and inclusive of their needs and concerns. Its essence lies in creating opportunities for the development of novel forms of knowledge, study, and action that are capable of delving into the knowledge and wisdom of people and places (Muhl and others, Reference Muhl2023). It is a process that involves working together with humans, and also nonhumans-others, towards a common end, where science, even though essential, is not privileged as the sole legitimate way of knowing.

The knows and hows of knowledge coproduction

What do we coproduce? How do we do it? And what is our role in that process? The concepts outlined above indicate that the paradigm of knowledge coproduction heralds a transformative approach to building new knowledge in the field of glaciology. Applying the theory demands the re-evaluation of traditional researcher roles and the development of interpersonal competencies, as the knowledge creation derives from complex social interactions that are specific to a particular situation. Within these synergistic interactions, the participants make sense of reality and negotiate its meaning to jointly define and solve a problem (Brugnach and Ingram, Reference Brugnach and Ingram2012). Hence, the development of actionable knowledge necessitates concentrated efforts among individuals, groups, or organisations.

Several authors have argued that the coproduction process entails three different stages: codesign, codevelopment, and codelivery (Wyborn and others, Reference Wyborn2019; Fleming and others, Reference Fleming2023). Here we suggest an additional preparation stage (see Fig. 3), as a precursor of any collaborative process of coproduction.

  1. (1) The preparation stage includes the identification and involvement of relevant participants and their positionality, as well as the securing of cultural safety (Bourassa and others, Reference Bourassa2020; Holmes, Reference Holmes2020). See Ford and others (Reference Ford2019) for an example that integrates Indigenous knowledge with science to quantify the impact of climate change on trail access in the Inuit Nunangat (Canada), where preparatory co-production plays a crucial role in shaping the development and outcomes of a modelling framework.

  2. (2) The codesign stage consists of identifying joint objectives, creating a common ground and equifinal problem definitions (Gray, Reference Gray1989), and designing the processes and procedures that are used to derive new knowledge. If the design is responsive to feedback, these activities may continue beyond the initial stage, fostering equitable partnerships.

  3. (3) The codevelopment stage encompasses the management of the actual coproduction of knowledge, including the logistics, relationships, and individual capacities. To address issues of scale and power, the researcher has to switch between being a reflective scientist, mediator, and facilitator. Furthermore, it demands the ability to embrace ambiguity and eventual conflicts that arise when integrating different perspectives with, for instance, dialogue learning and negotiations (Brugnach and Ingram, Reference Brugnach and Ingram2012; Chambers and others, Reference Chambers2021; McCabe and others, Reference McCabe, Parker, Osegowitsch and Cox2023).

  4. (4) The codelivery stage consists of jointly delivering the completed project and sustaining the coproduction. One measure is ensuring the application and ongoing maintenance of the new knowledge within the community, industry, government, etc.

Figure 3. Visualisation of knowledge coproduction in glaciology.

During the proposed four-stage cyclic process, it is crucial to acknowledge that pertinent local actors may encounter barriers preventing their engagement, for example, due to a lack of willingness or financial constraints, necessitating situation-specific strategies (Wyborn and others, Reference Wyborn2019). Hence, our proposed four-stage process of knowledge coproduction differs in many ways from the scientific method: it does not represent a replacement for the scientific method, but rather a complementary approach, which demands the application and development of new skills. This approach aligns with the call for scientists to engage in more meaningful and respectful collaborations with Indigenous communities, as highlighted by Wong and others (Reference Wong, Ballegooyen, Ignace, Johnson and Swanson2020) in their ten calls to action towards reconciliation.

Taking on the social and environmental responsibility of the new knowledge creation means emphasising inter- and transdisciplinary collaborations, which go beyond science to include multiple knowledge forms and engage nonscientific actors. Thus, coproduction processes require a high level of reflexivity and trust among all actors. Moreover, implementing those processes demands people skills like justice, care, humility, courage, cultural competency, and sensitivity to carefully account for all actors involved or affected, including conflict resolution skills (Caniglia and others, Reference Caniglia2023; David-Chavez and others, Reference David-Chavez2024). The complexity added by the collaborative process of knowledge coproduction is likely to be offset by the unveiling of deeper insights that might be difficult to attain through unilateral means (Fox and others, Reference Fox2020).

Conclusion

Nor would it concern them [the indigenous peoples who contributed to the early Arctic exploration] for an instant that their names should be left off the maps of the Arctic; after all, they had their own names for the snowy peaks and the frozen inlets that formed their world. It is not their loss that the map ignores them; it is our own.

Pierre Berton (Reference Berton1988), pp. 630–631

This work constitutes a reflection on the meaning and significance of knowledge coproduction in the field of glaciology. Starting from Seligman's (Reference Seligman1961) classical definition of glaciology, we invoked the paradigm of Structure–Form–Environment Interplay (SFEI; Faria and others, Reference Faria2009, Reference Faria, Kipfstuhl and Lambrecht2018) to formulate a modern definition of glaciology that reveals the relevance of knowledge coproduction. The adoption of a relational view of knowledge led us to identify five core dimensions of knowledge coproduction: purpose, ethics, ambiguity, inclusion/exclusion, and relationships. Based on those dimensions, we delved into the decisive methodological aspects of the coproduction process, namely the definition of its purpose, the identification of participants, the organisation of the process, the recognition of ambiguity in WoKs, and the consideration of ethical implications (Brugnach and Ingram, Reference Brugnach and Ingram2012, Reference Brugnach, Ingram, Weber, Lach and Steel2017). In doing so, we were able to bring a deeper insight into the implications, drawbacks, and benefits associated with the generation of glaciological knowledge through inter- and transdisciplinary collaborative processes.

The recent literature recognises three different stages of any knowledge coproduction process: codesign, codevelopment, and codelivery (Wyborn and others, Reference Wyborn2019; Fleming and others, Reference Fleming2023). Here, we propose the inclusion of an additional preparation stage, which entails the acknowledgment of the identity and involvement of all human and nonhuman participants, their positionality, and means to ensure their cultural and ontological safety. Such a preparation stage is fundamental to highlight and manage uneven power relations, which are often unavoidably formed from the start (Turnhout and others, Reference Turnhout, Metze, Wyborn, Klenk and Louder2020).

Unfortunately, many attempts at glaciological coproduction still neglect some of the aforementioned process stages, not living up to their original expectations, and limiting their scope to the mere appropriation of knowledge from the less empowered. Such failures are often related to the preservation of existing structures of power that privilege scientific knowledge over other WoKs (Carey and others, Reference Carey, Jackson, Antonello and Rushing2016; Yua and others, Reference Yua, Raymond-Yakoubian, Daniel and Behe2022). In glaciology, as in any other complex interdisciplinary fields, knowledge coproduction can be viewed as a process that connects different WoKs by bringing together the expertise and skills of a wide range of actors in ways that are fair and inclusive of their needs and concerns. Its essence lies in creating opportunities for the development of novel forms of knowledge, study, and action, which are capable of delving into the knowledge and wisdom of people and places. It is a process that involves working together with humans and nonhumans towards a common end, where science, even though essential, is not privileged as the sole legitimate way of knowing.

From the perspective presented here, knowledge coproduction does not replace the scientific method, but rather complements it. By doing so, it provides a wider scope to create knowledge, which is not only scientifically robust, but also relevant and actionable for addressing real-world challenges. It is usually a gradual process, as achieving mutual understanding and trust requires considerable time and commitment from each participant. Nevertheless, it is likely to unveil deeper insights, and possibly even paradigm shifts (Kuhn, Reference Kuhn1996), which might be difficult to attain through unilateral means.

Acknowledgements

This research is part of the ‘MENDindi’ project PIBA_2022_1_0043 funded by the Basque Government, and supported by the Spanish Government through Ref. CEX2021-001201-M funded by MCIN/AEI/10.13039/501100011033. We extend our deepest gratitude to Patricia Muñoz-Marzagon (IzotzaLab, BC3) for her valuable comments and revisions, and to the participants of the IGS International Symposium on Ice in a Sustainable Society (Bilbao, 5–10 June 2022) for their inspiring discussions. We also appreciate the thoughtful and constructive feedback provided by the two anonymous reviewers.

Authors’ contributions

Conceptualization, methodology, supervision, funding acquisition, resources, project administration, data curation and validation: M. B. (lead) and S. H. F. Investigation and writing (original draft): M. B. (lead), S. H. F., S. S. B., L. K., N. B. B. Visualisation: L. K. and S. H. F.

Footnotes

1 Secretariat of the Antarctic Treaty; url: https://www.ats.aq.

2 See also Hook L and Mander B (2018) The fight to own Antarctica. Financial Times, 24 May 2018. Retrieved on 2 April 2024; url: https://www.ft.com/content/2fab8e58-59b4-11e8-b8b2-d6ceb45fa9d0.

3 See also Craciun A and 9 others (2022) Icy Humanities: A Collaborative Symposium. Online workshop hosted on 5 April 2022 by The Frederick S. Pardee Center for the Study of the Longer-Range Future at Boston University's Pardee School of Global Studies and the Scott Polar Research Institute at the University of Cambridge; url: https://youtu.be/vJhjUWTkchA.

References

Abdel-Fattah, D, Trainor, S, Hood, E, Hock, R and Kienholz, C (2021) User engagement in developing use-inspired glacial lake outburst flood decision support tools in Juneau and the Kenai Peninsula, Alaska. Frontiers Earth Science 9, 635163. doi: 10.3389/feart.2021.635163CrossRefGoogle Scholar
Achermann, D (2020) Vertical glaciology: the second discovery of the third dimension in climate research. Centaurus 62, 720743. doi: 10.1111/1600-0498.12294CrossRefGoogle Scholar
Albert, TF (2000) The influence of Harry Brower, Sr., an Iñupiaq Eskimo hunter, on the bowhead whale research program conducted at the UIC-NARL facility by the North Slope Borough. In Norton, D (ed.), Fifty More Years Below Zero: Tributes and Meditations for the Naval Arctic Research Laboratory's First Half Century at Barrow, Alaska. Fairbanks, AK, USA: University of Alaska Press, pp. 265278.Google Scholar
Arnstein, SR (1969) A ladder of citizen participation. Journal of the American Planning Association 35(4), 216224. doi: 10.1080/01944366908977225Google Scholar
Asayama, S and 29 others (2023) Three institutional pathways to envision the future of the IPCC. Nature Climate Change 13, 877880. doi: 10.1038/s41558-023-01780-8CrossRefGoogle Scholar
Babu, S (2023) Adaptation in the scientific method: an outline for mutual learning and knowledge co-production in climate science. Science, Technology & Society 28(4), 621638. doi: 10.1177/09717218231197448Google Scholar
Bandola-Gill, J, Arthur, M and Leng, RI (2022) What is co-production? Conceptualising and understanding co-production of knowledge and policy across different theoretical perspectives. Evidence & Policy 19(2), 275298. doi: 10.1332/174426421X16420955772641CrossRefGoogle Scholar
Bazai, NA and 8 others (2021) Increasing glacial lake outburst flood hazard in response to surge glaciers in the Karakoram. Earth-Science Reviews 212, 103432. doi: 10.1016/j.earscirev.2020.103432CrossRefGoogle Scholar
Beck, S, Forsyth, T and Mahony, M (2022) Urgent need to move toward solution-oriented environmental assessments. One Earth 5(6), 586588. doi: 10.1016/j.oneear.2022.05.021CrossRefGoogle Scholar
Berton, P (1988) The Arctic Grail. New York, NY, USA: Viking.Google Scholar
Bhargava, HK, Power, DJ and Sun, D (2007) Progress in web-based decision support technologies. Decision Support Systems 43(4), 10831095. doi: 10.1016/j.dss.2005.07.002CrossRefGoogle Scholar
Bourassa, C and 12 others (2020) Ethical research engagement with Indigenous communities. Journal of Rehabilitation and Assistive Technologies Engineering 7, 18. doi: 10.1177/2055668320922706CrossRefGoogle Scholar
Bouwen, R (1998) Relational construction of meaning in emerging organizational contexts. European Journal of Work and Organizational Psychology 7, 299319. doi: 10.1080/135943298398727CrossRefGoogle Scholar
Bouwen, R and Taillieu, T (2004) Multi-party collaboration as social learning for interdependence: developing relational knowing for sustainable natural resource management. Journal of Community & Applied Social Psychology 14(3), 137153. doi: 10.1002/casp.777CrossRefGoogle Scholar
Bravo, MT (2006) Science for the people: northern field stations and governmentality. British Journal of Canadian Studies 19(2), 221245. doi: 10.3828/bjcs.19.2.8CrossRefGoogle Scholar
Bravo, MT (2009) Voices from the sea ice: the reception of climate impact narratives. Journal of Historical Geography 35(2), 256278. doi: 10.1016/j.jhg.2008.09.007CrossRefGoogle Scholar
Bravo, MT (2017) A crypolitics to reclaim our frozen material states. In Kowal, E and Radin, J (eds), Cryopolitics: Frozen Life in a Melting World. Cambridge, MA, USA: MIT Press, pp. 2758.CrossRefGoogle Scholar
Bravo, M and Rees, G (2006) Cryo-politics: environmental security and the future of Arctic navigation. The Brown Journal of World Affairs 13(1), 205215.Google Scholar
Bravo, MT and Triscott, N (eds) (2011) Arctic Geopolitics and Autonomy. Berlin, Germany: Hatje Cantz.Google Scholar
Bremer, S and Meisch, S (2017) Coproduction in climate change research: reviewing different perspectives. WIREs Climate Change 8(6), e482. doi: 10.1002/wcc.482CrossRefGoogle Scholar
Brugnach, M (2017) The space in between: where multiple ways of knowing in water management meet. Special Issue on Helen Ingram's contributions to water, environment, and policy scholarship. Journal of the Southwest 59(1–2), 3459. doi: 10.1353/jsw.2017.0005CrossRefGoogle Scholar
Brugnach, M and Ingram, H (2012) Ambiguity: the challenge of knowing and deciding together. Environmental Science & Policy 15, 6071. doi: 10.1016/j.envsci.2011.10.005CrossRefGoogle Scholar
Brugnach, M and Ingram, H (2017) Ways of knowing and relational knowledge. In Weber, E, Lach, D and Steel, B (eds), New Strategies for Wicked Problems: Science and Solutions in the 21st Century. Corvallis, OR, USA: Oregon State University Press, pp. 2743.Google Scholar
Brugnach, M and Özerol, G (2019) Knowledge coproduction and transdisciplinarity: opening Pandora's box. Water 11(10), 1997. doi: 10.3390/w11101997CrossRefGoogle Scholar
Brugnach, M, Dewulf, A, Henricksen, HJ and van der Keur, P (2011) More is not always better: coping with ambiguity in natural resources management. Journal of Environmental Management 92(1), 7884. doi: 10.1016/j.jenvman.2010.08.029CrossRefGoogle Scholar
Brugnach, M, Craps, M and Dewulf, A (2017) Including indigenous peoples in climate change mitigation: addressing issues of scale, knowledge and power. Climatic Change 140(1), 1932. doi: 10.1007/s10584-014-1280-3CrossRefGoogle Scholar
Bruley, E, Locatelli, B and Lavorel, S (2021) Nature's contributions to people: coproducing quality of life from multifunctional landscapes. Ecology and Society 26(1), 12. doi: 10.5751/es-12031-260112CrossRefGoogle Scholar
Burton, JW (2022) Political ecology of glaciology: against a ‘neutral’ science in the Anthropocene. Abstract C12A–10 presented at AGU Fall Meeting, 12–16 Dec 2022. Available at https://agu.confex.com/agu/fm22/meetingapp.cgi/Paper/1132162Google Scholar
Büttner, L and 7 others (2023) Science under pressure: how research is being challenged by the 2030 Agenda. Sustainability Science 18, 15691574. doi: 10.1007/s11625-023-01293-5CrossRefGoogle Scholar
Caniglia, G and 14 others (2023) Practical wisdom and virtue ethics for knowledge coproduction in sustainability science. Nature Sustainability 6, 493501. doi: 10.1038/s41893-022-01040-1CrossRefGoogle Scholar
Carey, M and Moulton, H (2023) Inequalities of ice loss: a framework for addressing sociocryospheric change. Annals of Glaciology 64(91), 6776. doi: 10.1017/aog.2023.44CrossRefGoogle Scholar
Carey, M, Jackson, M, Antonello, A and Rushing, J (2016) Glaciers, gender, and science: a feminist glaciology framework for global environmental change research. Progress in Human Geography 40(6), 770793. doi: 10.1177/0309132515623368CrossRefGoogle Scholar
Carmona, R and 6 others (2023) Analysing engagement with Indigenous peoples in the intergovernmental panel on climate change's sixth assessment report. npj Climate Action 2, 29. doi: 10.1038/s44168-023-00048-3CrossRefGoogle Scholar
Chambers, JM and 41 others (2021) Six modes of co-production for sustainability. Nature Sustainability 4, 983996. doi: 10.1038/s41893-021-00755-xCrossRefGoogle Scholar
Chen, D and 14 others (2021) Framing, context, and methods. In Masson-Delmotte, V and 18 others (eds), Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge, UK: Cambridge University Press, pp. 147286. doi: 10.1017/9781009157896.003Google Scholar
Chown, SL and Brooks, CM (2019) The state and future of Antarctic environments in a global context. Annual Review of Environment and Resources 44, 130. doi: 10.1146/annurev-environ-101718-033236CrossRefGoogle Scholar
Craps, M, Dewulf, A, Mancero, M, Santos, E and Bouwen, R (2004) Constructing common ground and re-creating differences between professional and indigenous communities in the Andes. Journal of Community and Applied Social Psychology 14(5), 378393. doi: 10.1002/casp.796CrossRefGoogle Scholar
Cruikshank, J (2005) Do Glaciers Listen? Local Knowledge, Colonial Encounters, and Social Imagination. Vancouver, Canada: UBC Press.Google Scholar
David-Chavez, DM and 4 others (2024) A values-centered relational science model: supporting Indigenous rights and reconciliation in research. Ecology and Society 29(2), 11. doi: 10.5751/ES-14768-290211CrossRefGoogle Scholar
Davis, K and 8 others (2021) From participatory engagement to coproduction: modelling climate-sensitive processes in the Arctic. Arctic Science 7(4), 699722. doi: 10.1139/as-2020-0032CrossRefGoogle Scholar
De Landa, M (2006) A New Philosophy of Society: Assemblage Theory and Social Complexity. London, UK: Continuum.Google Scholar
de Pomereu, J (2019) All but blank: artistic approaches to human Antarctica. Polar Record 55(5), 337340. doi: 10.1017/S0032247419000421CrossRefGoogle Scholar
Dodds, K, Hemmings, AD and Roberts, P (eds) (2017) Handbook on the Politics of Antarctica. Cheltenham, UK: Elgar.CrossRefGoogle Scholar
Drenkhan, F and 5 others (2023) Looking beyond glaciers to understand mountain water security. Nature Sustainability 6, 130138. doi: 10.1038/s41893-022-00996-4CrossRefGoogle Scholar
Elzinga, A (1993) Antarctica: the construction of a continent by and for science. In Crawford, E, Shinn, T and Sörlin, S (eds) Denationalizing Science: The Contexts of International Scientific Practice. Sociology of the Sciences Yearbook, Vol. 16. Dordrecht, The Netherlands: Springer, pp. 73106.CrossRefGoogle Scholar
Faria, SH (2009) The multidisciplinary ice core. Low Temperature Science 68(Suppl.), 3537. Available at http://hdl.handle.net/2115/45428Google Scholar
Faria, SH (2023) Introduction to the Annals of Glaciology ‘Ice in a Sustainable Society’ issue. Annals of Glaciology 64(91), 5556. doi: 10.1017/aog.2024.13CrossRefGoogle Scholar
Faria, SH and 6 others (2009) The multiscale structure of Antarctica. Part I: inland ice. Low Temperature Science 68(Suppl.), 3959. Available at http://hdl.handle.net/2115/45430Google Scholar
Faria, SH, Kipfstuhl, S and Lambrecht, A (2018) The EPICA-DML Deep Ice Core: A Visual Record. Berlin, Germany: Springer.CrossRefGoogle Scholar
Farinotti, D, Immerzeel, WW, de Kok, RJ, Quincey, DJ and Dehecq, A (2020) Manifestations and mechanisms of the Karakoram Glacier Anomaly. Nature Geoscience 13, 816. doi: 10.1038/s41561-019-0513-5CrossRefGoogle ScholarPubMed
Feldman, MS, Khademian, AM, Ingram, H and Schneider, AS (2006) Ways of knowing and inclusive management practices. Public Administration Review 66(1), 8999. doi: 10.1111/j.1540-6210.2006.00669.xCrossRefGoogle Scholar
Fleming, A and 14 others (2023) Perceptions of co-design, co-development and co-delivery (Co-3D) as part of the coproduction process – insights for climate services. Climate Services 30, 100364. doi: 10.1016/j.cliser.2023.100364CrossRefGoogle Scholar
Ford, JD and 6 others (2016) Including Indigenous knowledge and experience in IPCC assessment reports. Nature Climate Change 6(4), 349353. doi: 10.1038/nclimate2954CrossRefGoogle Scholar
Ford, JD and 7 others. (2019) Changing access to ice, land and water in Arctic communities. Nature Climate Change 9, 335339. doi: 10.1038/s41558-019-0435-7CrossRefGoogle Scholar
Fox, S and 7 others (2020) Connecting understandings of weather and climate: steps towards co-production of knowledge and collaborative environmental management in Inuit Nunangat. Arctic Science 6(3), 267278. doi: 10.1139/as-2019-0010CrossRefGoogle Scholar
Fung, A (2006) Varieties of participation in complex governance. Public Administration Review 66(1), 6675. doi: 10.1111/j.1540-6210.2006.00667.xCrossRefGoogle Scholar
Gerlak, AK and 11 others (2023) Stakeholder engagement in the coproduction of knowledge for environmental decision-making. World Development 170, 106336. doi: 10.1016/j.worlddev.2023.106336CrossRefGoogle Scholar
Gioli, G, Khan, T and Scheffran, J (2014) Climatic and environmental change in the Karakoram: making sense of community perceptions and adaptation strategies. Regional Environmental Change 14, 11511162. doi: 10.1007/s10113-013-0550-3CrossRefGoogle Scholar
Gray, B (1989) Collaborating: Finding Common Ground for Multiparty Problems. San Francisco, CA, USA: Jossey-Bass.Google Scholar
Harrison, S and 14 others (2018) Climate change and the global pattern of moraine-dammed glacial lake outburst floods. The Cryosphere 12, 11951209. doi: 10.5194/tc-12-1195-2018CrossRefGoogle Scholar
Hauser, DDW and 9 others (2021) Co-production of knowledge reveals loss of indigenous hunting opportunities in the face of accelerating Arctic climate change. Environmental Research Letters 16(9), 095003. doi: 10.1088/1748-9326/ac1a36CrossRefGoogle Scholar
Hernandez, J, Meisner, J, Jacobs, LA and Rabinowitz, PM (2022) Re-centering Indigenous knowledge in climate change discourse. PLOS Climate 1(5), e0000032. doi: 10.1371/journal.pclm.0000032CrossRefGoogle Scholar
Hewitt, K (2005) The Karakoram Anomaly? Glacier expansion and the ‘elevation effect,’ Karakoram Himalaya. Mountain Research and Development 25(4), 332340. doi: 10.1659/0276-4741(2005)025[0332:TKAGEA]2.0.CO;2CrossRefGoogle Scholar
Holmes, AGD (2020) Researcher positionality – a consideration of its influence and place in qualitative research – a new researcher guide. Shanlax International Journal of Education 8(4), 110. doi: 10.34293/education.v8i4.3232CrossRefGoogle Scholar
Honeybun-Arnolda, E, Mahony, M and Chilvers, J (2024) Ecologies of co-production in the Anthropocene. Progress in Environmental Geography 3(2), 115136. doi: 10.1177/27539687241245427CrossRefGoogle Scholar
Hovelsrud, GK, Poppel, B, van Oort, B and Reist, JD (2011) Arctic societies, cultures, and peoples in a changing cryosphere. AMBIO 40(Suppl. 1), 100110. doi: 10.1007/s13280-011-0219-4CrossRefGoogle Scholar
Howarth, C, Lane, M, Morse-Jones, S, Brooks, K and Viner, D (2022) The ‘co’ in co-production of climate action: challenging boundaries within and between science, policy and practice. Global Environmental Change 72, 102445. doi: 10.1016/j.gloenvcha.2021.102445CrossRefGoogle Scholar
Huggel, C and 5 others (2020) Anthropogenic climate change and glacier lake outburst flood risk: local and global drivers and responsibilities for the case of lake Palcacocha, Peru. Natural Hazards Earth System Science 20, 21752193. doi: 10.5194/nhess-20-2175-2020CrossRefGoogle Scholar
Hughes, KA and 10 others (2018) Antarctic environmental protection: strengthening the links between science and governance. Environmental Science & Policy 83, 8695. doi: 10.1016/j.envsci.2018.02.006CrossRefGoogle Scholar
Immerzeel, and 31 others (2020) Importance and vulnerability of the world's water towers. Nature 577, 364369. doi: 10.1038/s41586-019-1822-yCrossRefGoogle ScholarPubMed
IPCC (2019) IPCC Special Report on the Ocean and Cryosphere in a Changing Climate (SROCC). Pörtner HO and 12 others (eds). Cambridge, UK: Cambridge University Press. doi: 10.1017/9781009157964Google Scholar
Jasanoff, S (ed.) (2004) States of Knowledge: The Co-Production of Science and the Social Order. London, UK: Routledge.CrossRefGoogle Scholar
Joyner, C (1986) Legal implications of the concept of the common heritage of mankind. International & Comparative Law Quarterly 35(1), 190199. doi: 10.1093/iclqaj/35.1.190CrossRefGoogle Scholar
Jull, J, Morton-Ninomiya, M, Compton, I and Picard, A (2018) Fostering the conduct of ethical and equitable research practices: the imperative for integrated knowledge translation in research conducted by and with indigenous community members. Research Involvement and Engagement 4, 45. doi: 10.1186/s40900-018-0131-1CrossRefGoogle ScholarPubMed
Kennicutt, M and 10 others (2014) Polar research: six priorities for Antarctic science. Nature 512, 2325. doi: 10.1038/512023aCrossRefGoogle ScholarPubMed
Kettle, NP and 5 others (2019) Linking Arctic system science research to decision maker needs: co-producing sea ice decision support tools in Utqiaġvik, Alaska. Polar Geography 43(2–3), 206222. doi: 10.1080/1088937X.2019.1707318CrossRefGoogle Scholar
Klenk, N, Fiume, A, Meehan, K and Gibbes, C (2017) Local knowledge in climate adaptation research: moving knowledge frameworks from extraction to co-production. WIREs Climate Change 8(5), e475. doi: 10.1002/wcc.475CrossRefGoogle Scholar
Kuhn, TS (1996) The Structure of Scientific Revolutions, 3rd Edn. Chicago, IL, USA: University of Chicago Press.CrossRefGoogle Scholar
Latulippe, N and Klenk, N (2020) Making room and moving over: knowledge co-production, Indigenous knowledge sovereignty and the politics of global environmental change decision-making. Current Opinion in Environmental Sustainability 42, 714. doi: 10.1016/j.cosust.2019.10.010CrossRefGoogle Scholar
Laybourn-Parry, J, Tranter, M and Hodson, AJ (2012) The Ecology of Snow and Ice Environments. Oxford, UK: Oxford University Press.CrossRefGoogle Scholar
Lejano, R and Ingram, H (2009) Collaborative networks and new ways of knowing. Environmental Science & Policy 12(6), 653662. doi: 10.1016/j.envsci.2008.09.005CrossRefGoogle Scholar
Lemos, MC and 20 others (2018) To co-produce or not to co-produce. Nature Sustainability 1, 722724. doi: 10.1038/s41893-018-0191-0CrossRefGoogle Scholar
Lepenies, R, Hüesker, F, Beck, S and Brugnach, M (2018) Discovering the political implications coproduction in water governance. Water 10(10), 116. doi: 10.3390/w10101475CrossRefGoogle Scholar
López-Martínez, J (2020) Humans in Antarctica: science and policy. In Oliva, M and Ruiz-Fernández, J (eds), Past Antarctica. London, UK: Academic Press, pp. 279288.CrossRefGoogle Scholar
Lutz, AF and 7 others (2022) South Asian agriculture increasingly dependent on meltwater and groundwater. Nature Climate Change 12, 566573. doi: 10.1038/s41558-022-01355-zCrossRefGoogle Scholar
Maas, T, Pauwelussen, A and Turnhout, E (2022) Co-producing the science–policy interface: towards common but differentiated responsibilities. Humanities and Social Sciences Communications 9, 93. doi: 10.1057/s41599-022-01108-5CrossRefGoogle Scholar
Mahoney, A, Eicken, H and Shapiro, L (2007) How fast is landfast sea ice? A study of the attachment and detachment of nearshore ice at Barrow, Alaska. Cold Regions Science and Technology 47, 233255. doi: 10.1016/j.coldregions.2006.09.005CrossRefGoogle Scholar
Mahony, M and Hulme, M (2018) Epistemic geographies of climate change: science, space and politics. Progress in Human Geography 42(3), 395424. doi: 10.1177/0309132516681485CrossRefGoogle Scholar
McCabe, A, Parker, R, Osegowitsch, T and Cox, S (2023) Overcoming barriers to knowledge coproduction in academic–practitioner research collaboration. European Management Journal 41(2), 212222. doi: 10.1016/j.emj.2021.11.009CrossRefGoogle Scholar
McGee, J and Liu, N (2019) The challenges for Antarctic governance in the early twenty-first century. Australian Journal of Maritime & Ocean Affairs 11(2), 7377. doi: 10.1080/18366503.2019.1634940CrossRefGoogle Scholar
Miller, CA and Wyborn, C (2020) Co-production in global sustainability: histories and theories. Environmental Science & Policy 113, 8895. doi: 10.1016/j.envsci.2018.01.016CrossRefGoogle Scholar
Moors, EJ and 14 others (2011) Adaptation to changing water resources in the Ganges basin, northern India. Environmental Science & Policy 14(7), 758769. doi: 10.1016/j.envsci.2011.03.005CrossRefGoogle Scholar
Moses, SK, Whiting, AV, Bratton, GR, Taylor, RJ and O'Hara, TM (2009) Inorganic nutrients and contaminants in subsistence species of Alaska: linking wildlife and human health. International Journal of Circumpolar Health 68(1), 5374. doi: 10.3402/ijch.v68i1.18294CrossRefGoogle ScholarPubMed
Muhl, EK and 13 others (2023) Transitioning toward ‘deep’ knowledge co-production in coastal and marine systems: examining the interplay among governance, power, and knowledge. Ecology and Society 28(4), 17. doi: 10.5751/ES-14443-280417CrossRefGoogle Scholar
Munir, R, Bano, T, Adil, IH and Khayyam, U (2021) Perceptions of glacier grafting: an indigenous technique of water conservation for food security in Gilgit-Baltistan, Pakistan. Sustainability 13(9), 5208. doi: 10.3390/su13095208CrossRefGoogle Scholar
Norström, AV and 35 others (2020) Principles for knowledge coproduction in sustainability research. Nature Sustainability 3, 182190. doi: 10.1038/s41893-019-0448-2CrossRefGoogle Scholar
Orlove, B, Wiegandt, E and Luckman, BH (2008) The place of glaciers in natural and cultural landscapes. In Orlove, B, Wiegandt, E and Luckman, BH (eds), Darkening Peaks: Glacial Retreat, Science, and Society. Berkeley, CA, USA: University of California Press, pp. 319.CrossRefGoogle Scholar
Quaghebeur, K, Masschelein, J and Nguyen, HH (2004) Paradox of participation: giving or taking part? Journal of Community and Applied Social Psychology 14(3), 154165. doi: 10.1002/casp.776CrossRefGoogle Scholar
Radin, J and Kowal, E (eds) (2017) Cryopolitics: Frozen Life in a Melting World. Cambridge, MA, USA: MIT Press.CrossRefGoogle Scholar
Rashidi, P (2024) Indigenous peoples at the heritage–climate change nexus: examining the effectiveness of UNESCO and the IPCC's boundary work. Review of International Studies. Published online, 122. doi: 10.1017/S0260210524000196CrossRefGoogle Scholar
Robards, MD and 7 others (2018) Understanding and adapting to observed changes in the Alaskan Arctic: actionable knowledge coproduction with Alaska Native communities. Deep Sea Research Part II: Topical Studies in Oceanography 152, 203213. doi: 10.1016/j.dsr2.2018.02.008CrossRefGoogle Scholar
Robel, AA, Ultee, L, Ranganathan, M and Nash, M (2024) For whom and by whom is glaciology? Journal of Glaciology. Published online, 111. doi: 10.1017/jog.2024.29CrossRefGoogle Scholar
Salim, E, Ravanel, L, Bourdeau, P and Deline, P (2021) Glacier tourism and climate change: effects, adaptations, and perspectives in the Alps. Regional Environmental Change 21, 120. doi: 10.1007/s10113-021-01849-0CrossRefGoogle ScholarPubMed
Sandré, T, Wardekker, A and Gherardi, J (2024) While waiting for the sea ice: stories of changes from Ittoqqortoormiit (Kalaallit Nunaat). In Bremer, S and Wardekker, A (eds), Changing Seasonality: How Communities are Revising their Seasons. Berlin, Germany: De Gruyter, pp. 6166. doi: 10.1515/9783111245591-007CrossRefGoogle Scholar
Seligman, G (1961) The definition of ‘glaciology’. Journal of Glaciology 3(29), 802802. doi: 10.3189/S0022143000027155Google Scholar
Smith, HA and Sharp, K (2012) Indigenous climate knowledges. WIREs Climate Change 3(5), 467476. doi: 10.1002/wcc.185CrossRefGoogle Scholar
Sörlin, S (2009) Narratives and counter-narratives of climate change: north Atlantic glaciology and meteorology, c.1930–1955. Journal of Historical Geography 35(2), 237255. doi: 10.1016/j.jhg.2008.09.003CrossRefGoogle Scholar
Tadaki, M (2017) Rethinking the role of critique in physical geography. The Canadian Geographer 61(1), 7383. doi: 10.1111/cag.12299CrossRefGoogle Scholar
Thompson, KL, Lantz, T and Ban, NC (2020) A review of Indigenous knowledge and participation in environmental monitoring. Ecology and Society 25(2), 10/11027. doi: 10.5751/ES-11503-250210CrossRefGoogle Scholar
Turner, N and Clifton, H (2009) ‘It's so different today’: climate change and indigenous lifeways in British Columbia, Canada. Global Environmental Change 19, 180190. doi: 10.1016/j.gloenvcha.2009.01.005CrossRefGoogle Scholar
Turnhout, E, Metze, T, Wyborn, C, Klenk, N and Louder, E (2020) The politics of co-production: participation, power, and transformation. Current Opinion in Environmental Sustainability 42, 1521. doi: 10.1016/j.cosust.2019.11.009CrossRefGoogle Scholar
UNTT (2013) Global Governance and Governance of the Global Commons in the Global Partnership for Development Beyond 2015. New York, NY, USA: Thematic Think Piece of the United Nations System Task Team on the Post-2015 United Nations Development Agenda (UNTT), UN-OHCHR, UN-OHRLLS, UNDESA, UNEP and UNFPA. Available at http://www.un.org/en/development/desa/policy/untaskteam_undf/thinkpieces/24_thinkpiece_global_governance.pdfGoogle Scholar
Wong, C, Ballegooyen, K, Ignace, L, Johnson, MJ and Swanson, H (2020) Towards reconciliation: 10 Calls to Action to natural scientists working in Canada. Facets 5(1), 769783. doi: 10.1139/facets-2020-0005CrossRefGoogle Scholar
World Ocean Review (2019) Chapter 5: polar politics and commerce. In Gelpke, N (ed.), World Ocean Review 6: The Arctic and Antarctic – Extreme, Climatically Crucial and In Crisis. Hamburg, Germany: Maribus, pp. 238295.Google Scholar
Wyborn, C and 7 others (2019) Co-producing sustainability: reordering the governance of science, policy, and practice. Annual Review of Environment and Resources 44, 319346. doi: 10.1146/annurev-environ-101718-033103CrossRefGoogle Scholar
Yua, E, Raymond-Yakoubian, J, Daniel, RA and Behe, C (2022) A framework for coproduction of knowledge in the context of Arctic research. Ecology and Society 27(1), 34. doi: 10.5751/ES-12960-270134CrossRefGoogle Scholar
Zingraff-Hamed, A and 8 others (2020) Stakeholder mapping to co-create nature-based solutions: who is on board? Sustainability 12(20), 8625. doi: 10.3390/su12208625CrossRefGoogle Scholar
Figure 0

Figure 1. Schematic representation of the Structure–Form–Environment Interplay (SFEI). The environment acts on form and structure; changes in form affect structure and environment; the structure influences form and environment.

Figure 1

Figure 2. Core dimensions of knowledge coproduction.

Figure 2

Figure 3. Visualisation of knowledge coproduction in glaciology.