Fig 1.
A citation network of documents with differing impacts.
Document ‘A’ is a document with seemingly high impact: therefore citation from document A to document X could be weighed by the ‘impact’ of document A. However, it is clear that document A receives its high impact status from documents P, Q, R and S, which are themselves low impact documents. The documents P, Q, R and S could have been deliberately created to give more credibility to A. Similarly, document B which is also a high impact document receives its high impact status from low impact documents. Therefore, the citation counts of documents cannot be directly used to weigh the citations, since these weights themselves could be manipulated. A more nuanced approach is therefore necessary.
Fig 2.
The process of computing pagerank-index.
Stage I involves running pagerank algorithm on the citation network and obtaining a pagerank value for each paper. Stage II involves assigning a suitably weighted proportion of each pagerank value to the authors of the corresponding paper. Stage III involves summing all pagerank value ‘shares’ an author has obtained, comparing it with other authors in the community and assigning a percentile value to that author accordingly. The considered community could be the world scientific community at large, or a subset thereof.
Fig 3.
Spread of the h-index for each manipulative and non-manipulative author (as absolute values) in the first simulation scenario.
For authors of similar seniority, the ‘manipulative’ author group has a clear advantage.
Fig 4.
Spread of the pagerank-index for each manipulative and non-manipulative author (as absolute values) in the first simulation scenario.
Neither group of authors have a clear advantage here.
Fig 5.
Variation of average h-index and pagerank-index for non-manipulative and manipulative authors at each timestep for simulation scenario 1.
The difference is much smaller between the two groups when pagerank-index is considered.
Fig 6.
Variation of h-index and pagerank-index for highest ranking non-manipulative and manipulative authors at each timestep for simulation scenario 1.
Fig 7.
The spread of h-index for collaborative and non-collaborative authors (as absolute values) in scenario 2.
For authors of a similar level of seniority (as indicated by their IDs), the ‘collaborative’ authors have a clear advantage.
Fig 8.
The spread of pagerank-index for collaborative and non-collaborative authors (as absolute values) in scenario 2.
No group of authors have a clear advantage over the other group.
Fig 9.
Variation of average h-index and pagerank-index for collaborative and non-collaborative authors at each timestep in simulation scenario 2.
The difference between groups is much smaller when pagerank-index is used.
Fig 10.
Variation of h-index and pagerank-index for highest ranking collaborative and non-collaborative authors at each timestep in simulation scenario 2.
The difference between groups is much smaller when pagerank-index is used.
Fig 11.
The spread of h-index for quantity oriented authors and quality oriented authors (as absolute values) in scenario 3.
Considering authors with the same level of seniority (as indicated by the IDs), the ‘quantity-oriented’ authors have a clear advantage over ‘quality-oriented’ authors.
Fig 12.
The spread of h-index for quantity oriented authors and quality oriented authors (as absolute values) in scenario 3.
No group of authors have a clear advantage over the other group.
Fig 13.
Variation of average h-index and pagerank-index for quantity oriented authors and quality oriented authors at each timestep in scenario 3.
The difference between groups is much smaller when pagerank-index is used.
Fig 14.
Variation of h-index and pagerank-index for highest ranking quality oriented authors and quantity oriented authors at each timestep in scenario 3.
The difference between the highest ranking authors is much smaller when pagerank-index is used.
Table 1.
The top 12 scientists as ordered by their h-index in the field of quantum game theory.
Table 2.
The top 12 scientists as ordered by their pagerank-index in the field of quantum game theory.
Fig 15.
Part of the collaboration network highlighting authors R. Han (h-index: 8, pagerank-index: 79.6%), X. Xu (h-index: 8, pagerank-index: 95.1%), J. Wu (h-index: 1, pagerank-index: 89.3%), and M. Shi (h-index: 3, pagerank-index: 79.1%) in the field of Quantum Game Theory.
Fig 16.
Part of the collaboration network highlighting the prominent authors from the Quantum Game Theory Google Scholar profile.
The details of the highlighted authors are listed in Table 2.
Fig 17.
Part of the collaboration network highlighting P. Frackiewics (h-index:1 (h-index percentile 55.5%),pagerank-index:98.4%).
It is clear that this author plays an important role in the field by being the ‘bridge’ between two sets of authors who work perhaps in two sub-fields. Note that though the collaboration network is not an input in computing the pagerank-index, the pagerank-index is able to recognize and reward authors who perform such an important role in the development of the field, as indicated by the relatively high pagerank-index of this author. The h-index, being a relatively simplistic citation count measure, fails to recognize this fact.
Fig 18.
The h-index and pagerank-index of the best 5% authors (according to h-index) in the field of quantum game theory.
Since the pagerank-index is a percentile, percentile values were used for the h-index as well, rather than actual h-index values. Note here that the pagerank-index value varies from 70% to 100%. That is, some authors who are among the top 5% in terms of h-index are not even among the top 25% when pagerank-index is considered.
Fig 19.
(A) The variation of h-index and pagerank-index for two groups of authors during the evolution of quantum game theory field. The x-axis corresponds to each new paper added and the time line of the evolution is from 1955 to 2014. One group of authors are classified as ‘collaborative’ and another group as ‘non-collaborative’. The way this classification was done is explained in the text. It is clear that while the h-index favours the ‘collaborative’ authors, the pagerank-index, in general, tends to favour the ‘non-collaborative’ authors. (B) The average ‘papershare’ of collaborative and non-collaborative authors during the evolution of quantum game theory field. The ‘papershare’ is calculated as the summation of proportional contributions made to papers. For example, if an author has contributed two papers each with two other co-authors, he has a total of 4/3 paper-shares. It is clear that the ‘non-collaborative’ authors work harder and have more ‘paper-shares’ than collaborative authors. Contrasting with part (A), we may see that the pagerank-index highlights this fact by favouring the ‘non-collaborative’ authors, while the h-index arguably unfairly favours collaborative authors who on average produce less ‘paper-shares’.
Table 3.
The top 12 scientists as ordered by their h-index in the HEP-TH dataset.
Table 4.
The top 12 scientists as ordered by their pagerank-index in the HEP-TH dataset.
Fig 20.
The h-index and pagerank-index of the best 5% authors (in terms of h-index) in the HEP-TH dataset.
Since the pagerank-index is a percentile, percentile values were used for the h-index as well, rather than actual h-index values. Note here that the pagerank-index value varies from 65% to 100%. That is, some authors who are among the top 5% in terms of h-index are not even among the top 25% when pagerank-index is considered.