Scholars have long been captivated by the idea that knowledge generation is outpacing their ability to keep up, necessitating creative techniques and solutions to organize, manage, and access information. From scientist Vannevar Bush’s memex[1] to futurist Richard Buckminster Fuller’s Geoscope,[2] researchers have envisioned high-tech tools for information management and knowledge creation since before the advent of big data. Today, well into the era of hyperlinked text and geographic information systems not unlike the miracle tools envisioned by 20th century inventors, making knowledge on even very specific areas of scholarship tractable remains a complicated challenge. As scholarly knowledge continues to grow, so does interest in quantitative techniques for summary, survey, and synthesis of knowledge domains.

Knowledge mapping is one such survey and synthesis technique. It combines data visualization and network analysis to depict large collections of information spatially, as if they were a landscape viewed from above. Knowledge mapping is a general term for an analysis informed by and applied in multiple areas of scholarship, including information science [Börner 2010], literature [Moretti 2007], history [Graham, Milligan, and Weingart 2015], and bibliometrics [Chen 2016]. These maps are at once analytical, managerial, and communicative: analytical because they provide tests of network theories and because bibliometric data was one of the earliest sources of big data for such analyses; managerial because they guide decision-making, funding allocation, and evaluation; and communicative because they aim to support discovery and guide hypothesis formation by depicting knowledge as a collaborative, interlinked whole. Knowledge maps are simultaneously rhetorically powerful (because they make visual arguments) and ethically fraught (because visual arguments presented in such charts are often accepted as objective fact), but knowledge mapping techniques have not yet been brought into conversation with recent work in digital humanities surrounding ethical visualization and data feminism [D’Ignazio 2019]; [D’Ignazio and Klein 2020]; [Hepworth 2017]; [Hepworth 2020].

Ethical visualization is the practice of acknowledging and mitigating the potential for harm that is inherent to particular visualizations [Hepworth and Church 2018]. Ethical visualization and data feminism require consideration of the whole data pipeline, from acquisition to analysis to visualization, and attention to the ways in which some perspectives are marginalized, omitted, or elided [D’Ignazio and Klein 2016]; [D’Ignazio and Klein 2020]. Both traditions require not only acknowledging the potential negative effects of a visualization or drawbacks of a particular dataset, but actively working to mitigate them in a way that increases understanding while minimizing harm [Cairo 2014]. Given nascent discussions in bibliometrics about the potential harm perpetuated by uncritical application of bibliometric techniques for evaluation, it is an important time to bring critical practices into conversations about knowledge mapping [Bornmann 2017]; [Conway 2014]; [Donovan 2019]; [Furner 2014]; [Rolf 2021]; [Zuccala 2016].

In this paper, we demonstrate how principles of ethical visualization and data feminism can be applied in the development of a knowledge map to produce a more trustworthy and more useful product. We do this by providing a detailed account of the path we followed to build a knowledge map of climate communication research, highlighting practical challenges encountered in creating such a visualization and how ideas from ethical visualization literature helped navigate them. Specifically, we: (1) demonstrate the importance of critical practices in the development of a complex type of chart, (2) illustrate the intertwined nature of analysis and results in big data projects, and (3) take a first step toward a feminist bibliometrics informed by critical work in digital humanities. This addresses a previously identified need for clear guidance on the visual communication of knowledge networks [Conway 2014]; [Gavrilova, Kudryavstev, and Grinberg 2019]. It has relevance for digital humanists working with knowledge networks and bibliometricians seeking practical strategies for mitigating harmful externalities of evaluative bibliometrics. It also enriches ongoing conversations in the digital humanities about ethical visualization and data feminism with examples of how frequently ethical choices arise in a data visualization project.

Ultimately, we emphasize the constructedness of these types of visualizations, showing why a purely quantitative, purely objective depiction of a knowledge network is neither possible nor particularly useful. We argue that the best way to produce an effective knowledge map is to produce an ethical one, which requires attention to the ways trust and accountability can be produced at every step of analysis and production.

Knowledge maps are powerful tools for planning, collaborating, teaching, and communicating, because they depict metaknowledge about how topics and problems are structured [Börner 2010]; [Evans and Foster 2011]. Metaknowledge – literally, knowledge about knowledge – may sound like a dangerously totalizing “god trick,” but it can in fact be understood as a concept gesturing at the positionality and situatedness of all knowledge, and the necessity of combining multiple partial perspectives to understand a system [Haraway 1988]; [D’Ignazio 2019]. Sociologists James A. Evans and Jacob G. Foster define metaknowledge as the result of “critical scrutiny of what is known, how, and by whom” and suggest that we might best understand what metaknowledge is by thinking about what we, as individual scholars with particular trainings, career paths, and expertise, think about as we read a journal article in order to “index a broader context of ideas, [scholars], and disciplines” – the kind of knowledge gained from being a participant in a system through time [Evans and Foster 2011, 721]; [Kwan 2002]. Knowledge maps offer an alternative way to gain a similar kind of qualitative understanding via quantitative techniques, affording viewers an intuitive summary of a large collection of information [Lima 2011]; [Moretti 2007]; [van Geenen and Wieringa 2020]. Metaknowledge is important because it sparks abduction, or diagnostic-style logic, where experts may arrive intuitively at a conclusion based on partial information combined with their existing understanding of the system and situation at hand, and where knowledge may be generated instead of simply synthesized [Brooke 2017]; [Douven 2017]; [Graham, Milligan, and Weingart 2015].

While it may be preferable to gain metaknowledge the traditional way, by participating in a knowledge system over a lifetime, this is not always practical or possible. Knowledge maps act as a tool which – just like regular maps of landscapes – are useful for sharing information, for planning where to go and how to get there, for noticing patterns or pathways that might not have been apparent to boots on the ground, and for coordinating collective effort in the face of complexity. They support switching between general knowledge and specific pieces of information and evidence, an ability which has been identified as a fundamental practice of critical scholarship [Edmond 2018]; [Moretti 2007]; [Kwan 2002]. Their utility comes even though knowledge offered by such a bird’s eye view is clearly different from the kind gained through personal experience, immersion, and reflection [Evans and Foster 2011]; [Moretti 2007]. Essentially, it is worth simultaneously being cautious about the algorithmic ways in which knowledge maps synthesize big citation data and present it as knowledge, while also emphasizing the incredible utility of this form for producing, transmitting, and constructing collective knowledge [D’Ignazio and Klein 2016]; [D’Ignazio 2019]. Bibliometrician David A. Pendlebury summed this up effectively when he observed a need for “charting a path between the simple and false and the complex and unusable” [Pendlebury 2019, 549].

When constructed in partnership with residents from the mapped research domain, knowledge maps can prompt identification and reassessment of taken-for granted assumptions and highlight forces shaping problem definition in a field. In fact, examples of this work in climate domains are what initially inspired our attempt to map the climate communication research landscape [Canon, Boyle, and Hepworth 2022]. For example, informationist Christopher Belter and climate scientist Dian Seidel [Belter and Seidel 2013] created network visualizations to reveal (dis)connections in geoengineering knowledge, using sparse network charts to show how some planetary systems receive more focus than others, and that lack of information exchange between areas of study means there may be inadequate consideration of potential interactions between different geoengineering strategies. Another example is the work of psychologist Laura Kati Corlew and her team [Corlew et al. 2015], who successfully used social network analysis to build a knowledge sharing and resource discovery tool for climate professionals in the Pacific Islands.

These projects are notable because they leverage knowledge maps as communication and collaboration tools while being sensitive to audience needs and effects on those depicted in the visually powerful network charts. Rather than viewing analysis as an endpoint, these studies distill the information spaces into clear visualizations for interested audiences. Knowledge maps should be built from this perspective, to be both useful and usable and to assist viewers in extracting meaning from information spaces and analyses that may otherwise be esoterically complex.

The climate communication knowledge mapping project was initially situated in the tradition of science mapping, a kind of knowledge mapping undertaken by computer scientists and network analysts. Science mapping uses bibliometric data to reveal the structure of a knowledge domain by creating networks of papers or authors linked by citations or collaborations. However, despite having domain expertise in climate communication and fluency in network analysis techniques (often considered the ideal for this type of project), we immediately ran into ethical and practical challenges that were not well addressed in the science mapping literature, perhaps because too much emphasis is placed on the objectivity of network maps, the assumed impartiality of algorithmic curation, and the potential of data speaking for itself [Conway 2014]; [D’Ignazio 2019]; [D’Ignazio and Klein 2020]; [Hepworth 2020]; [White and McCain 1998]; [Yang et al. 2016]. In our project, limited technological resources necessitated static depictions of the knowledge network, data quality precluded purely algorithmic curation, and it was frequently unclear how fundamental tasks like disambiguation and layout should be approached when the goal was to create a useful knowledge map (instead of just to arrive at an analytical result). In this section, we describe in detail the challenges encountered in building the climate communication knowledge map and point out how attention to conversations in ethical visualization and data feminism provided needed guidance on navigating them.

Perhaps because of the impact of scientific approaches to visualization on knowledge mapping, a significant amount of data in knowledge mapping projects is not pre-processed before it is visualized. It is thought that network analysis itself controls for any errors or ambiguities in the underlying data [Chen 2016]. If ambiguities do exist in the network map, conventional wisdom holds that resulting irregularities cancel each other out, and overall conclusions are not affected [Fegley and Torvik 2013]; [White and McCain 1998]. We did not find this to be the case in our knowledge map, especially when imagining how it might be useful and trustworthy for climate communicators. If the first thing a user notices when looking at a knowledge map is a data error (such as a single leading scholar being split into multiple author nodes), it cannot be expected that the user will trust other elements of the knowledge map. Given that the point of a knowledge map is to support reasonable inferences about the structure and function of the research domain, it is a serious problem if data issues affect interpretation. Engineer Jinseok Kim’s research reveals the nature and extent of factors that distort knowledge maps [Kim, Kim, and Diesner 2014]; [Kim et al. 2014]; [Kim and Diesner 2016]; [Kim 2019]. For example, datasets rife with author name ambiguities appear scale-free,[3] a feature long thought to characterize citation networks [de Solla Price 1965], when in fact they aren’t. Consequences to both the mapped research community and to theorists studying network processes can be profound when data visualizations uncritically display conclusions that may be based on irregularities in the data, and when funding decisions are made based on this data. As a result, the bulk of our paper focuses on data processing, and the ethical considerations that may be glossed over when the network analysis itself is the jumping off point for a knowledge mapping study.

In this section, we undertake the important data feminist approach of showing our work [D’Ignazio and Klein 2020]. We provide a complete description of how we produced the climate communication knowledge map, attempting to be transparent about elements of data preparation and visualization design that are not generally discussed in published literature, but which are of vital importance in following an ethical and accountable process of visualization design [Callaway et al. 2020]; [D’Ignazio and Klein 2020]; [Hepworth and Church 2018]. All described data management and network analysis was conducted in Python with metaknowledge [McLevey and McIlroy-Young 2017] and NetworkX [Hagberg, Schult, and Swart 2008]. Visualization was performed with Gephi [Bastian, Heymann, and Jacomy 2009].

Ethical and effective visualizations of knowledge networks must inspire trust in two key groups: people depicted in the knowledge map, and people using the map to acquire knowledge or make decisions. We draw on our experience in the climate communication knowledge mapping project and on previous work on ethical visualization in the digital humanities to offer ethical visualization strategies for network data and knowledge maps specifically. This represents an important step in “ downscaling ” recommendations from ethical visualization and data feminism to demonstrate their application and utility in specific projects. We encourage readers to consult other literature on ethical visualization (especially [Lima 2011] and [Gavrilova, Kudryavstev, and Grinberg 2019] for discussions of additional visual conventions specific to the design of network charts.

Our recommendations are intended to assist researchers in balancing tensions between quantitative and qualitative, and objective and subjective, aspects of knowledge mapping. We advocate a humanistic approach to visualization design, recognizing that working with this type of data successfully requires coupling quantitative fluency with the more humanities-oriented practice of contextualizing findings, and tolerance for and transparency around the trial-and-error approach necessary to creating a useful product [Conway 2014]; [Dragga and Voss 2011]; [Drucker 2011]; [Hepworth and Church 2018]; [Stephens and Applen 2016]. As the climate communication knowledge mapping project illustrates, a purely quantitative, purely objective depiction of a knowledge network is neither possible nor particularly useful.

We began this paper with the observation that scholars have long been captivated by the quest to develop high-tech tools for information management and knowledge synthesis. From the vantage point of the 21st century, we recognize that the success of these tools is not simply a matter of technological progress, but one that requires ethical thought. Just as a network mapping platform like Gephi provides the technical tools for working with big network data, an ethical visualization framework provides the ethical tools for reducing the harm and increasing the impact of knowledge maps – essentially, for making them deliver on their promise of augmenting our perceptual abilities when faced with large and complex information spaces. In this paper, we have drawn on lessons learned in the climate communication knowledge mapping project to offer strategies for ethical and effective visualizations of knowledge networks. This approach acknowledges the potential for harm that comes with such visualizations and works actively to mitigate it. Taking an ethical approach to knowledge mapping is vital because the choices made in such an analysis determine whose and which contributions are ultimately legible.

We have attempted to provide guidelines for knowledge mappers seeking to support users in synthesizing and selecting meaningful insights from the mapped domain. Our recommendations balance tensions between qualitative and quantitative and objective and subjective aspects of knowledge mapping. They demonstrate the importance of critical practices in the development of knowledge maps, illustrate the intertwined nature of analysis and results in such projects, and emphasize the constructedness of the visualization. We show the only way to produce an effective knowledge map is to produce an ethical one, which requires attention to the ways trust and accountability can be produced at every step of analysis and production.

This framework for ethical visualization of knowledge networks contributes to early conversations about a feminist bibliometrics and demonstrates the direct relevance of digital humanities tools to work carried out across diverse other fields. Connecting bibliometrics literature with digital humanities discourse invites more qualitative and interpretive perspectives into bibliometric knowledge mapping, demonstrating that the data-centric and science-focused techniques frequently applied to knowledge network visualization may fail to produce a useful and impactful portrait of a knowledge domain without attending to these ethical concerns. A central purpose of this paper is to offer a clear example of the utility of a critical approach to knowledge mapping in a traditional knowledge mapping project.

The idea of separating wheat from chaff is a common trope in knowledge mapping. While knowledge mapping can absolutely facilitate discovery of relevant or applicable knowledge, assuming this is its key strength overlooks its real potential. Essentially, a system-level depiction may provoke a reassessment of what is wheat and what is chaff, and recognition that these designations are situation-dependent. As knowledge production increases and we continue to rely on quantitative and visual tools to help us navigate information spaces, it may be best to abandon the threshing trope and instead adopt a more kaleidoscopic model of knowledge mapping’s goals. Knowledge maps provide meaningful and multipurpose ways for individuals to explore a knowledge domain, and different individuals may need to turn the kaleidoscope in unique ways to find useful or compelling information and explanations which gel with, and usefully complement, their own experiences of a knowledge network.