Sample

The sample was derived from journal articles published within the category “Economics” as indicated in the Social Sciences Citation Index (Anon. 2019c). The SSCI is one of the most extensive data bases and part of the “Web of Science.” It is published by the US-American company Clarivate Analytics, which formerly belonged to Thomson Reuters. The period of time analyzed was 2005 to 2014. Therefore, it should be possible to identify changes which might have occurred after 2007-2008, the years in which the global economic and financial crisis took place, by comparison with the time before. Considering that it may take up to two years for economic research to react to any crisis by collecting and analyzing data as well as communicating the results in scientific publications, most publications referring to the crisis should not appear before 2009-2010. Therefore, we chose the period with the crisis in the first third of the time and analyzed the index terms of the journal papers. Additionally, a regional limitation was applied in order to reduce the complexity of the sample. Thus, only articles published by German-speaking authors or author collectives with at least one writer associated with an institution localized in a German-speaking region were considered.^{Footnote 8} This results in a sample of 11,934 documents and 26,031 index terms. The index terms were either calculated by computer programs within the SSCI (called “Keywords PLUS”) or defined by the respective authors themselves. Index terms name the area(s) of research that are picked up in the article. Simultaneously, they differentiate between areas of knowledge and research. Furthermore, they localize the articles in certain cognitive and social contexts, in which the texts as well as the authors (prefer to) operate.

The distribution of keywords is shown in Table 1. During the period of time investigated, both the number of documents and the number of keywords in each time phase increased. In total, the sample contained 372 documents not labelled with a keyword. Out of 11,934 documents this was 3.12 per cent. The maximum number of keyword groups a single document referred to was 27 in the last period. In total, the maximum number of keywords (before classifying them into groups of words) was 37 as identified by the program SciMAT (Cobo, López-Herrera, Herrera-Viedma, and Herrera Reference Cobo, López-Herrera, Herrera-Viedma and Herrera2012; see also Brixy Reference Brixy2014).

Table 1. Distribution of keywords

Notes: Number of Documents; Groups of words/Index terms: Number of groups of words formed by congruent or similar keywords; Min: Minimum number of keywords per document; Max: Maximum number of keywords per document; Mean: Average number of keywords per document; Median: Median of keywords per document; Standard deviation: Standard deviation of the values

Procedure

In order to answer the questions formulated above, a co-word analysis was carried out using SciMAT (Cobo et al. Reference Cobo, López-Herrera, Herrera-Viedma and Herrera2010). A co-word analysis is a bibliographic analytical instrument dedicated to the study of written communication (Jovanović Reference Jovanović2012). The foundation of the investigation are articles published in scientific journals, focusing on the keywords describing those articles. In this context the co-word analysis is advantageous, considering keywords, as one of the primary bases for scientific communication in economics, are taken into account. (e.g. Leininger Reference Leininger2009). It is a two-dimensional analytical method for detecting “co-occurrences” of two terms and can be characterized as an explorative analytical research approach (e.g. Döring and Bortz Reference Döring and Bortz2016). Co-occurrences exist when linguistic entities appear together in the same text document. In this study, a co-occurrence exists when two terms describe the same document (see also Dees Reference Dees2014). A term is defined as an amount of distinguishable meanings referring to certain objects.^{Footnote 9} Describing co-occurrences of certain terms across a certain number of documents allows us to uncover the underlying network structure of the relevant topics in economics and their thematic development over time.

The final result is a term-document matrix depicted in a network illustration. Index terms describe texts in a certain topical field or establish topical links. This procedure results in the categorization of terms into topic clusters, which can be visualized using statistical procedures. By comparing the visualizations of the five periods of time over the years 2005-2014, it is possible to draw conclusions about the development of the field examined. “Nodes” (n) and “lines” (l) are the essential elements of the network. The lines between the nodes are undirected, i.e. a direction going from one node to another cannot be observed. The link, however, is established equally from both nodes. In this study the nodes represent index terms (key terms) and lines between nodes represent co-occurrences of the index terms. Nodes and lines lead to a term-document-matrix A in which the factor a _ij is defined as the edge (line) weight, i.e. how often term j appears in document i (e.g. Coulter et al. Reference Coulter, Monarch and Konda1998; Havemann and Scharnhorst Reference Havemann, Scharnhorst, Stegbauer and Häußling2010). For network visualization, clusters are created in five steps:

1. 1) Calculation of the Equivalence Index:

For every pair of terms i and j, a value e _ij describing the intensity of their connection is determined, which indicates the frequency of co-occurrence. This equivalence index e _ij (Neff and Corley Reference Neff and Corley2009) is calculated by the formula

(1) $${e_{ij}} = {c_{ij}^2 \over c_i \cdot c_j}$$

whereby c _ij refers to the number of documents in which two index terms i and j occur together. By dividing c² _ij by the occurrence frequencies of the index terms c _i andc _j the measure of co-occurrence already is standardized. Whenever two index terms always appear together, the equivalence index reaches the value of one. If they never appear together in one of the documents, the value is zero.

1. 2) Clustering

The result of step 1) is a network of nodes (index terms) and weighted lines (equivalence index). In order to gain further insight into possible structures within the network, the complexity is reduced by clustering. The clusters are subcategories containing those terms that can be localized closer to each other than to other terms. An ideal cluster can be characterized as follows: It should be discrete and the proportion of the original data set (“coverage”) should be as high as possible. Special algorithms in this step allow the clustering of the index terms. In this case, we used the Simple Centers Algorithm, following Dees (Reference Dees2014). This offers the advantage of an automatic generation of cluster names by taking the minimal occurrence as well as the co-occurrence and the minimum and the maximum number of terms listed in the cluster into account. The visualization is made up of bipartite networks. Threshold values calculated in pre-tests are necessary for this process. There are no existing standards for this step. The threshold values should lead to a clear result presentation with a preferably sensible depth of detail: The maximum number of words contained in a cluster should not be more than 200, as the depiction would become too confusing with a higher density of words (Cobo et al. Reference Cobo, López-Herrera, Herrera-Viedma and Herrera2012). Pre-tests showed the threshold value of four as the minimum number occurrences in this analysis, that is, in order to create clusters that meet the aim formulated above. With every following time stage, this value had to be increased by one to still meet the aim formulated above. This need to increase the threshold values could be explained by a different approach by authors over time, when deciding which keywords to use. The automated keyword generation of the SSCI (“Keywords PLUS”) could also be a reason. Therefore, the increase in threshold values is not necessarily an indication of a growing diversity among the applied keywords. In the last time stage, the index terms should appear together in at least eight documents to form a cluster – all index terms where this was not the case were not considered in the calculation. This simultaneously complies with the median of the number of keywords dedicated to the documents in the sample. It is necessary for the threshold value for the first period of time to be smaller than those from the following periods. This is due to the fact that the number of documents was smaller in this period, as well as the number of index terms used for denoting the documents listed. Subsequently, the data set was reduced by another threshold value, which defines the minimum value of the co-occurrence of the keywords (i.e. the edge value). Pre-tests revealed an edge value of four to be appropriate for the first period of time (2005-2006). For the following periods, the appropriate values were as follows: 2007-2008: 6; 2009-2010: 8; 2011-2012: 9; 2013-2014: 12.

1. 3) Network Degrees of the Clusters

In this step the indices of density and centrality of each cluster within the network are calculated. These indices form the base of the cluster’s position in the strategic diagram as visualized in the following steps. By means of these indices, one can define the relevance of the cluster within the area of research analyzed. Density is a measure of the internal cohesion of the cluster. The higher the density, the more stable the cluster is, meaning either the interest in this topic will probably be longer-term in this research field, or indicating a more specialized field of research that is carried out by smaller scientific networks only. Option one favors the further development within the topic area that the cluster is built upon. There can be various outcomes for a dense but specific area of research: It may either heighten its relevance and centrality for the scientific field, or it remains in this specific position until its attraction or institutionalization diminishes. With regard to the scientific community, density can be interpreted as an indicator for the internal consensus between the researchers within this area (e.g. Renner Reference Renner1997). The higher the internal cohesion, the higher the consensus is regarding central theories and methods applied within the area of research. To calculate the density, the actual number of lines is divided by the possible number of lines:

(2) $$d = 100 \cdot {\sum\nolimits_{i,j = 1}^n {{e_{ij}}} \over n}$$

While i and j represent two index terms within a cluster, n refers to the total number of index terms in this cluster. The density reaches a value of one when all nodes are linked to each other and zero when there are no established linkages within the cluster.

The index of centrality C indicates the linkages of the network or the cohesion. The different options to calculate this index all take into account the total count of clusters in relation to the other clusters of the network, whereby the number of linkages realized is examined. The degree of centrality C is calculated as follows

(3) $$c = 10 \cdot \sum\nolimits_{u,v = 1}^n {{e_{uv}}}$$

whereby u and v each name an index term from different clusters. Depending on the result of the calculation, a cluster with a high degree of centrality can be characterized as highly relevant for the area of research. Meanwhile, a cluster with a low degree of centrality belongs rather to the “periphery” of the research field. If a scientist is aiming for (relevant) research in the area examined, he or she must deal with those topics with a high degree of centrality.

1. 4) Placement in the Strategic Diagram

The connection between the centrality and the density of a cluster in relation to its relevance for the whole field of research, as indicated by the degrees (see Bredillet Reference Bredillet2009; Dees Reference Dees2014), can be illustrated in a strategic diagram (see fig. 2 for the strategic diagrams calculated in our analyses). The zero position of the diagram is determined by the meridians of the indices of centrality and density. As depicted in fig. 2, centrality and density provide information about the significance of the cluster within a certain area of research. According to Dees (Reference Dees2014), the strategic diagram can be divided as follows: In quadrant 1 topics which are very central and well-developed are depicted. The clusters show a high internal as well as external degree of cross-linking. The core topics in the area of research are situated here. In the second quadrant clusters with a high relevance for the research field are depicted. Internally, these clusters are relatively underdeveloped, so that it is not possible to identify a single and homogeneous scientific frame where the topics are discussed. Those clusters are prominent in various approaches within the scientific field, processed in respect to different scientific problems and with diverse methods. Externally, the clusters are quite cross-linked. The rather general topics within the area of research appear here. The left section of the strategic diagram is assigned to the “peripheral” topics, i.e. less important for the area of research. In quadrant 3 the topics are still well-developed (indicated by the high density), while in quadrant 4 they are peripheral and undeveloped (as indicated by a low density and centrality). Clusters are not cross-linked much either internally or externally. Quadrant 3 thus indicates topics which are said to be “special” or adapted from other scientific disciplines, which are therefore clearly separable from other topics from the area of research.

1. 5) Temporal Changes in the Strategic Diagram

Scientific change occurs whenever a theme cluster changes its position within the strategic diagram or vanishes completely in the long-term. New clusters can appear in the diagram in the same way. Thus the dynamic is driven by a movement of keywords, altering their level of relevance for the scientific community. This affects the composition, relevance, as well as the topical focus of the clusters. Mutschke and Renner (Reference Mutschke, Renner, Mochmann and Gerhardt1995) regard the career of a research topic as a process in which a growing centrality is followed by a cycle also favoring a growing density of the cluster. A turning point in this career is reached when high degrees of both centrality as well as density can be identified, but the topic becomes increasingly less attractive for the research community, provoking shrinking degrees of centrality and density as one effect. A peripheral and sufficiently innovative and interesting research topic originating in quadrant 4 of the strategic diagram (peripheral and non-developed) can gradually be integrated into the first quadrant. Here, the research community sets its focus on this topic, so that its “maturity” can grow rapidly. Once interest in a topic declines, it will most likely drift into quadrant 3, also known as the “ivory tower of science,” where highly specific and relatively isolated research takes place. This describes a general cycle or dynamic of scientific trends (Mutschke and Renner Reference Mutschke, Renner, Mochmann and Gerhardt1995). Temporal changes within areas of research are depicted with the “overlapping items graph” and the “evolution map” (see figs. 1 and 3). In the overlapping items graph, the stability index indicates the numeric changes to the examined keywords. The stability index specifies the number of shared keywords between two neighboring periods of time in the five periods of time analyzed in this study. It is calculated by the formula

(4) $$item{s_{ij}} \div \left( {item{s_i} + item{s_j} - item{s_{ij}}} \right),$$

whereby i and j name two keywords from two different clusters. If the value is 1, the keywords between two periods are absolutely congruent. If it is 0 there are no shared items.

Notes: Inner circle: Number of keywords counted in the analysis; horizontal arrows: number of consistent keywords from two neighbouring periods; in brackets: stability index; arrows leading away: number of keywords which disappear from one period to the next; arriving arrows: number of new keywords in the period

Figure 1. Development of the number of keywords.

Figure 2. Strategic diagrams of the different time periods with clusters’ centrality and density within an area of research.

Notes: Circles: Amount of core documents contained in the clusters; Uninterrupted lines: Cluster names that are transferred from one period of time to the next; Dashed lines: Cluster of neighboring periods that share single keywords; Line thickness: inclusion index (thick lines – keywords within a cluster change little from one period to next)

Figure 3. Evolution map of all clusters 2005-2014.

The evolution map illustrates the differentiation of the theme clusters in a complete overview over all periods. Here, the inclusion index is calculated for the edge weight. The value 1 for the inclusion index stands for all index terms of one cluster being equivalent to those of the following cluster.

In the co-word analysis, the following steps were conducted: First, the data set was corrected. Duplicates, abbreviations, plural/singular, vocabulary in different languages, orthographic misspelling, as well as synonyms were identified and condensed into groups. The result of this procedure is 23,376 groups of terms containing between one and six index terms. Furthermore, 55 stopword groups were defined, which were excluded from the sample. Stopwords are terms that are regarded as irrelevant in regard to the analysis, or which would have distorted the analysis because of an extraordinary high frequency of occurrence. Considering our focus was on understanding the development of different theoretical approaches, we excluded methodological terms, codes, years, geographical information, or dates, although one could learn something from those terms, too. The selection of stopwords was conducted following the procedure proposed by (Dees Reference Dees2014, 152). Furthermore, the data was differentiated into five time periods. See Table 1 for the number of documents and index terms in each period of time.