2.1. Literature analysis

We conducted a literature analysis of papers published using the term resilience and several synonyms of undesirable resilience in WoS and Scopus academic literature collections from 1970 to 2018. Synonyms of undesirable resilience were identified during an interdisciplinary expert workshop held in Leipzig in 2018 and included undesirable resilience, institutional inertia, path dependency, lock-in, social traps, social-ecological traps, unhelpful resilience, maladaptation, perverse resilience and wicked resilience. This set of terms comprises a non-exhaustive list based on the input of participants from a range of disciplines (Supplementary Table S1). The term resilience was used as a benchmark for comparison. To precisely assess the number of resilience papers published that did not include our targeted terms, the total search results for resilience were subtracted by the sum of papers that included terms for perverse resilience, unhelpful resilience, undesirable resilience and wicked resilience. Searches for publications were performed between June and August 2018, filtered by terms used in their title, abstract and/or keywords. Based on a pilot analysis, the timespan for the literature search was divided into two periods – 1970–1999 and 2000–2018 – because a considerable number of synonyms of undesirable resilience emerged after 2000 (Figure 1). With this division, we wanted to check for temporal differences and avoid anachronistic comparisons in the usage of different terms.

^a The compound annual growth rate is a measure of percentage increase per year and thus expresses the exponential growth of papers published using the term resilience in comparison to the other terms above over the same time period.

Fig. 1. Total number of papers published per year using the term resilience and synonyms of undesirable resilience in their title, abstract and/or keywords in Web of Science since 2000 (and using the term resilience in Scopus). For terms emerging after 2000, first appearances are shown at the top of the figure. Total sums of papers published (and compound annual growth rate^a between 2000 and 2017) in Web of Science for the period were 41,479 (17.8%) for resilience, 9379 (5.7%) for lock-in, 2858 (8%) for path dependency and 1687 (10.6%) for social trap, whilst resilience in Scopus was 44,106 (16.5%). Trend lines for other terms are not shown due to total sum of papers below 1000 paper for the period, totalling 262 for institutional inertia, 977 for maladaptation, 132 for undesirable resilience, 39 for social-ecological trap, 11 for unhelpful resilience, 48 for wicked resilience and 9 perverse resilience.

For each term and time period in our dataset, we used the same terminology and categorization of scientific fields employed by WoS and Scopus: the former uses ‘broad research categories’ and ‘research areas’, while the latter uses ‘areas’ and ‘subject areas’ (Supplementary Figure S1). To conduct our search through the WoS ‘advanced research’ tool, each term was specified in the ‘topic’ field (covering title, abstract and/or keywords fields within a record) and the respective scientific disciplines were identified by specific ‘research area’ (e.g., Sociology) – each classified within ‘broad research categories’(e.g., Social Sciences). Search results were restricted to the document type ‘articles’, considering all languages, and to ‘research areas’ with more than 70,000 publications. To enable the selection of appropriate peer-reviewed published papers in the scientific fields and timeframes filtered, only ‘Science Citation Index Expanded (SCI-EXPANDED)’, ‘Social Sciences Citation Index (SSCI)’ and ‘Arts & Humanities Citation Index (A&HCI)’ were searched as citation indexes. In Scopus, the ‘advanced search’ tool was used to explore articles published across different scientific fields (defined as ‘subject areas’) that contained our selected terms of interest in the publication's title, abstract and/or keywords. Due to incompatible assignment of similar scientific fields between the two search engines, the data gathered were not merged and thus were analysed independently for WoS and Scopus.

2.2. Our integrative approach

We briefly describe the concept of undesirable resilience as social-ecological dynamics that reinforce vulnerabilities and/or hinder transformation towards sustainable development. ‘Synonyms’ used in this study are interpreted as different terms (i.e., linguistic and rhetoric elements) referring to identical or similar intentions or meanings of a concept (i.e., its ontology), but not necessarily to the same phenomena to which it applies (concept extension). This means that our argument for a ‘bridging concept’ does not intend to overwrite the nuances, specific processes or dimensions of terms described in their own literatures and contexts under a definitive unifying term. We rather aim to identify a term that can facilitate a common understanding of undesirable resilience and serve as a conceptual entry point for interdisciplinary communication. We find that there is potential for such a common understanding, because – although values, traditions and designs are inherently different across scientific disciplines – some features of the terms referring to undesirable resilience overlap (e.g., between perverse and undesirable resilience; between social trap, path dependency and lock-in).

2.3. Qualitative analysis: terms and academic disciplines

All terms analysed were discussed by the author team during the Leipzig workshop and their definitions were described based on key bibliography and how concepts currently are used in SES research primarily (Box 1). Relevant academic disciplines in WoS and Scopus were selected based on their similarities and relevance to the study of the terms identified. To balance the comparison of observations in our main analysis using all terms identified, the total number of disciplines selected was held equal for the two datasets (n = 9). In WoS, three broad research categories were explored: Arts & Humanities (AH), which included the research areas History and Philosophy (n = 2); Social Sciences (SS), including Business & Economics, Government & Law, Psychology and Sociology (n = 4); and Life Sciences & Biomedicine (LS), containing Agriculture, Behavioral Sciences and Environmental Sciences & Ecology (n = 3). In Scopus, four research categories were explored: Health Sciences (HS), including the subject area Medicine (n = 1); Life Sciences (LS), which contained Agricultural and Biological Sciences (n = 1); Physical Sciences (PS), consisting of Earth and Planetary Sciences and Environmental Science (n = 2); and Social Sciences (SS), composed of the following subject areas: Arts and Humanities; Business, Management and Accounting; Economics Econometrics and Finance; Psychology; and Social Sciences (n = 5).

A secondary analysis of 20 research areas specifically for the broad research categories of SS (n = 10) and for LS (n = 10) was conducted separately to further investigate the use of terms resilience, lock-in and undesirable resilience in WoS. The SS research areas included Area Studies, Business & Economics, Development Studies, Geography, Government & Law, International Relations, Psychology, Social Issues, Sociology and Urban Studies. Life Sciences & Biomedicine contained Agriculture, Anthropology, Behavioral Sciences, Biodiversity & Conservation, Developmental Biology, Environmental Sciences & Ecology, Evolutionary Biology, Marine & Freshwater Biology, Zoology and Public, Environmental & Occupational Health. A literature search for this secondary analysis was performed in February 2019, filtering publications by terms used in their title, abstract and/or keywords. Due to different categorizations, distinct assignments of academic disciplines and a more representative use of the term undesirable resilience in WoS from 2000 to 2018, this secondary analysis was not conducted in Scopus.

2.4. Quantitative analysis: frequency of use

Despite covering a substantial amount of the academic literature, no database is complete and balanced (Chadegani et al., Reference Chadegani, Salehi, Yunus, Farhadi, Fooladi, Farhadi and Ebrahim2013). Both databases contain biases that favour the frequency of natural, biomedical and engineering sciences over AH and SS (Mongeon & Paul-Hus, Reference Mongeon and Paul-Hus2016). To control for this potential limitation and increase the reliability of our analysis (i.e., comparing the number of papers published using the terms searched across different research areas), the number of articles published was standardized by the total number of papers published in each research area as follows: the standardized number of publications reflects the number of papers published using target terms (n) per total number of papers published in the research area (N) multiplied by one million (standard factor; i.e., expressed by papers per million papers):

$$n/N \times 10^6$$

2.5. Quantitative analysis: evenness of use

To test our hypothesis that synonyms for undesirable resilience are used within siloed, disconnected disciplinary approaches, we calculated the evenness in the use of terms in published papers across research areas (WoS) and subject areas (Scopus). For each term, the coefficient of variation (CV; described below) of the standardized number of publications (papers per million papers) was measured across academic disciplines.

CV expresses evenness of use by a simple calculation of standard deviation (σ) over the mean (μ). It reveals the degree of dispersion around the mean and thus is a useful measurement to compare variance even if the standardized number of publications shows highly different means for each of the terms assessed. This method has been used in ecology to assess the degree to which species abundance is spread evenly across discrete habitat types (Julliard et al., Reference Julliard, Clavel, Devictor, Jiguet and Couvet2006). In an analogous way, we use this metric to assess how the numbers of journal papers using a specific term are spread across different disciplines. We rank disciplines from the lowest to the highest CV value (i.e., from more to less even use of terms across disciplines; Julliard et al., Reference Julliard, Clavel, Devictor, Jiguet and Couvet2006), indicating terms that are more to less commonly shared across disciplines.

Additionally, Shannon–Wiener's (D^SW), Simpson's (D^S) and Berger–Parker's (D^PB) ecological indices (Baumgärtner, Reference Baumgärtner2006) were applied to analyse the equivalent richness, abundance and equitability (evenness) for each target term used across research areas. In our study, terms searched correspond to ‘species’ and research areas represent ‘communities’. The standardized numbers of publications were then ranked according to more to less even use of terms across disciplines (high to low values for D^PB and low to high values for all other metrics). The equations used are described below.

Richness (D^R) is the simplest measure of biodiversity of an ecosystem Ω and equates to the total number of different species found in that system (n). In our case, ‘species’ was equivalent to ‘terms’ and n represented how many times each term was found across the nine different research areas. This is often referred to as species richness:

$$D^R\lpar {\rm \Omega } \rpar = n$$

Shannon–Wiener entropy summarizes the entropy of a community. It expresses the average amount of ‘information’ in the community by comparing rare species ‘information’ to common species and their information value (proportional to the logarithm of their proportional abundance in the community, p_i). In our study, terms are equivalent to species and research areas are the communities.

$$H = {\rm \;}-\mathop \sum \limits_{i = 1}^n p_i{\rm \;}ln{\rm \;}p_i$$

Shannon–Wiener equitability (D^SW) is calculated by dividing the Shannon diversity index (entropy) by its maximum (H _max). Therefore, it varies between 0 and 1 (or 0% and 100%), with higher values indicating greater community evenness.

$$D^{SW} = H/H_{{\rm max}}$$

Simpson's index (D^S) refers to the probability that two randomly selected specimens from a sample will be of two different species. In theory, this metric ranges from 0 (perfectly uneven) to 1 (perfectly even). It expresses a true probability value.

$$D^S = 1{\rm \;}/\mathop \sum \limits_{i = 1}^n p_i^2 $$

Berger–Parker's index (D^PB) equals the maximum p_i value in the dataset (i.e., the proportional abundance of the most abundant type). If Berger–Parker's index is high, this means that the community is dominated by the most common species (i.e., it is not even).