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Article

Publication Performance and Trends in Mangrove Forests: A Bibliometric Analysis

by
Yuh-Shan Ho
1 and
Sharif A. Mukul
2,3,*
1
Trend Research Centre, Asia University, No. 500, Lioufeng Road, Wufeng, Taichung 41354, Taiwan
2
Tropical Forests and People Research Centre, University of the Sunshine Coast, Maroochydore DC, Buderim, OLD 4556, Australia
3
Department of Earth and Environment, Florida International University, Miami, FL 33199, USA
*
Author to whom correspondence should be addressed.
Sustainability 2021, 13(22), 12532; https://doi.org/10.3390/su132212532
Submission received: 22 October 2021 / Revised: 9 November 2021 / Accepted: 9 November 2021 / Published: 12 November 2021
(This article belongs to the Special Issue Mangrove Ecosystem Ecology, Conservation and Sustainability)
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Abstract

:
Mangroves are one the most productive ecosystems on Earth, and they are geographically located in the tropics and sub-tropics. Notwithstanding their critical role in providing a large number of environmental services and benefits as well as livelihood provisions, mangrove forests are being lost globally at an alarming rate. At the same time, they are increasingly recognized as a cost-effective nature-based climate solution for their carbon sequestration and storage capacity. Despite their enormous importance to people’s lives and the ecosystem, no bibliometric study on this topic has been published to our knowledge. Here, we provide a bibliometric analysis of the research on mangroves with research trends, most influential research based on citation count, and the origins (country and institution) of major research. Using the Science Citation Index Expanded (SCI-EXPANDED) database of the Web of Science Core Collection (Clarivate Analytics), we identified 13,918 documents published between 1990 and 2019. Nevertheless, 12,955 articles met our final criteria and were analyzed in detail. Six publications and their citations per publication (CPP2019) were applied to evaluate the publication performance of countries and institutes. When considering the top ten Web of Science subject categories, articles published on the ecology of mangroves had the highest CPP2019 of 28. Environmental sciences have been the major category since 2013. The USA dominated the total articles and single-author articles. The USA was also the most frequent partner of international collaborative publications. China published the most single-country articles, first-author articles, and corresponding-author articles. However, articles by the USA and Australia had a higher CPP2019. Sun Yat Sen University in China was the most active university. The Australian Institute of Marine Science dominated all kinds of publications with the top CPP2019. Together with the USA, Australia, China, India, Brazil, and Japan ranked both the top six on total publications and total publications in 2019. Our bibliometric study provides useful visualization of the past and current landscape of research on mangroves and emerging fields, to facilitate future research collaboration and knowledge exchange.

1. Introduction

Mangroves are located in the intertidal zones of coastal tropical and sub-tropical regions of the world (Figure 1) [1]. Globally, they occupy nearly 13.7 million ha of area and are distributed across 118 countries [2]. Mangroves are critical in providing a large number of environmental services and/or benefits, such as buffering coastlines against cyclones, tsunamis, and storm surges [3,4,5], carbon storage and sequestration [6], water quality regulation [7], provision of breeding habitats for many species of fish and wildlife [8], etc. Mangroves also support local livelihoods through the provision of ecotourism, food, fuel, timber, and construction materials [9,10]. A recent study suggests that the global flood protection benefits of mangroves are worth nearly USD 65 billion per year [11], while the cyclone protection value of mangroves is worth about USD 1.8 million/km2 per year [12].
Since mangroves are a major reservoir of global blue carbon [13] and can sequester carbon from the atmosphere faster than any other terrestrial ecosystems [14], they are increasingly regarded as a cost-effective nature-based climate solution in many parts of the world. In contrast to peatlands (another carbon rich ecosystem), mangroves also release negligible amounts of greenhouse gases per unit area [15]. Notwithstanding their enormous importance to people’s lives and their diverse environmental benefits, mangroves are lost globally at a rate faster than the tropical rainforests [16]. Climate change and the resulting sea-level rise, coastal infrastructure development, aquaculture, and conversion to agricultural land are amongst the major threats to this imperiled ecosystem [17,18].
Here, we provide a bibliometric analysis of the publication performance and research trends on mangroves using a systematic survey protocol [19,20,21]. We identified key areas of research and temporal changes in the research foci on mangroves worldwide. The study also provides critical insight into the impactful research on mangroves and their origin. Our analysis could be useful to design future research on mangroves and recognize the changing value of mangroves to people’s lives and nature.

2. Materials and Methods

The data relevant to the present study were derived from the SCI-EXPANDED in Clarivate Analytics Web of Science (updated on 27 January 2021). It was pointed out that the SCI-EXPANDED is designed mainly for researchers to find literature but not used for bibliometric studies [22,23]. Therefore, it is always necessary to have a data treatment but also to have data directly from SCI-EXPANDED for bibliometric studies. Recently, a big difference was found by using ‘front page’ [24] as filter in widely bibliometric studies [25,26]. KeyWords Plus supplied additional search terms extracted from the titles of articles cited by authors in their bibliographies and footnotes in the ISI (now Clarivate Analytics) database, and substantially augmented title-word and author-keyword indexing [27]. It was pointed out that the documents, which can only be searched out by KeyWords Plus, were irrelevant to the studied topic [20]. Search keywords “mangrove” and “mangroves” were used, which inevitably contain articles related to “mangrove forest” or “mangrove forests”. By using advanced search with TI (title), AB (abstract), and AK (author keywords), 13,918 documents, including 12,955 articles having the search keywords in their ‘front page’ [24] and including document title, abstract, and author keywords from 1990 to 2019, were defined as mangrove-related publications.
In the SCI-EXPANDED, the corresponding author is labelled as reprint author, but in this study, we used the term corresponding author [28]. In multiple corresponding-authors articles, only the last corresponding author, institute, and country were designated as the corresponding author information [29]. In a single-author article, where authorship is unspecified, the single author is both first and corresponding author [30]. Similarly, in a single institutional article, the institution is classified as the first as well as the corresponding author institution [30].
In order to have accurate analysis results, affiliations originating from England, Scotland, Northern Ireland, Wales, Cayman Islands, and Turks and Caicos (Turks and Caicos Islands) were reclassified as being from the UK (United Kingdom). Affiliations from Hong Kong before 1997 were reclassified as being from China [31]. Affiliations from French Guiana were reclassified as being from France [31]. Affiliations from Bonaire and Neth Antilles (Netherlands Antilles) were reclassified as being from Netherlands [32]. Affiliations from Greenland were reclassified as being from Denmark [33]. Affiliations from Senegambia were checked and reclassified as being from Senegal. Affiliations from USSR were checked and reclassified as being from Russia [34]. Affiliations from Czechoslovakia were checked and reclassified as being from Czech Republic [35]. Similarly, Czechoslovak Acad Sci (Czechoslovak Academy of Sciences) was checked and recorded as Czech Acad Sci (Czech Academy of Sciences).
To examine the citations received by the publications, four citation indicators were applied:
C0: the total number of citations from the Web of Science Core Collection in publication year [36].
Cyear: the total number of citations (in a particular year) from the Web of Science Core Collection. C2019 means the number of citations in 2019 [28].
TCyear: the total number of citations from the Web of Science Core Collection since publication year to the end of the most recent year [37]. In this study, this is 2019 (TC2019).
CPPyear: citations per publication (CPP2019 = TC2019/TP) [28].
When reporting the top ten most frequently cited articles based on total citations (TC2019), we considered the articles containing search keywords in their title or author keywords that are primarily focused on mangroves. Therefore, articles where mangroves were not the main focus or form only a small part within a larger context [38] we purposely excluded after carefully reviewing the abstract. We believed this approach would provide a more relevant and useful scenario of global trends and research on mangroves.

3. Results and discussion

3.1. Document Type and Language of Publication

A relationship between document types and citations per publication has been proposed [39]. In 2015, the citations per publication were improved by using the citation indicator of CPPyear, which gives values more accurately [40]. Recently, the number of authors per publication was also applied for the discussion of document types [41]. Table 1 shows the characteristics of 16 document types, including 12,955 articles (93% of the 13,918 documents) with a number of authors per publication (APP) of 4.3. It should be noticed that documents can be classified in two document types in the Web of Science Core Collection. For example, 10 documents were classified as book chapters and reviews. Thus, the total percentage was higher than 100% [21]. In addition, 642 proceedings papers were also classified as articles.
The book chapters document type had the highest CPP2019 of 84, which can be attributed to the five highly cited book chapters with a TC2019 of 100 or more [36] by Alongi [13], Balasubramanian et al. [42], Feller et al. [43], Thiel and Haye [44], and Manson et al. [45], with a TC2019 of 302, 159, 156, 148, and 124, respectively. The data papers document type had the highest APP of 7.0. Furthermore, the average number of authors per mangrove article was 4.3, with the maximum number of authors being 54 by Armisen et al. [46] from France, the USA, Germany, the UK, Canada, New Zealand, Russia, the Netherlands, and Panama.
Of all document types, only 12,955 articles were used for further analysis because they included the whole research, such as introduction, methods, results, discussions, and conclusions. The language of the publication is one of the basic concerns in bibliometric studies as a big data analysis [47]. There were 10 languages in use. English, as the most popular language, comprises 97% of the total articles, followed distantly by Spanish (164 articles; 1.3% of 12,955 articles), Portuguese (95; 0.73%), French (45; 0.35%), Chinese (19; 0.15%), and Japanese (14; 0.11%). Some other languages that were less used were as follows: Russian (9 articles), Malay (3), German (2), and Arabic (1). Articles published in English had a much higher CPP2019 of 20 than non-English articles with a CPP2019 of 5.5. Articles published in English had a higher APP of 4.3 than non-English articles with an APP of 3.4.

3.2. Characteristics of Publication Outputs

Ho proposed a relationship between the total annual number of articles (TP) and their citations per publication (CPPyear = TCyear/TP) by their years [48] to understand publications and their impact trends in a research topic. Figure 2 presents the distribution of the annual number of articles (TP) and their citations per publication (CPP2019) by year, which was expressed as TC2019/TP. The number of articles increased from 92 in 1990 to 309 in 2005, and then it increased sharply to 1050 in 2018 and 1049 in 2019. The year 2000, with 213 articles, had the highest CPP2019 of 44, followed by a CPP2019 of 41 and 40 in 2005 and 1998, respectively. This could be due to the increasing number of studies in recent years, which the authors cannot cite over time. Based on Figure 2, it takes CPPs about a decade to reach a plateau. Similarly, research topics related to the environment, for example environmental monitoring [49], wind tunnels [50], bioaccumulation [51], and Fenton oxidation for soil and water remediation [21], also took about one decade to reach a plateau. It might be concluded that to evaluate the impact of papers, citations accumulated after at least one decade are needed [52]. A total of 9854 mangrove articles (76% of 12,955 articles) had no citations in the publication year (C0 = 0). Although, with an increasing number of journals in SCI-EXPANDED, articles have had higher citations in the publication year (C0) in recent years [53]. Furthermore, among the top 100 C0 articles, 7.6% and 17% of them were among the top 100 TC2019 and C2019 articles, respectively.

3.3. Web of Science Categories and Journals

Journal Citation Reports (JCR) indexed 9381 journals across 178 Web of Science categories in SCI-EXPANDED in 2019. In order to know development trends among research fields and their interactions, a relationship between the number of articles in categories and publication years was proposed [54]. A total of 12,955 mangrove-related articles were published in 1655 journals, which are classified among the 136 Web of Science categories in SCI-EXPANDED. Altogether, 537 articles were published in 157 journals that were not in SCI-EXPANDED in 2019. Table 2 shows the top ten Web of Science categories with 500 articles or more. In 2019, 106 journals were classified in the category of marine and freshwater biology, which was the leading category with 3140 articles (24% of 12,955 articles). Comparing the top ten categories, mangrove articles published in the category of ecology had the highest CPP2019 of 28, followed by oceanography with a CPP2019 of 26 (Table 2). The average number of authors in the category of multidisciplinary sciences was 5.2, while in zoology it was 3.1. Figure 3 shows the developments of the top six categories in 2019. Mangrove articles were published mainly in categories of marine and freshwater biology and ecology from 1992 to 2008. The category of marine and freshwater biology was the most popular from 1990 to 2005. Environmental sciences have been the main category since 2013.
Multidisciplinary science is going to be a new category. It has been noticed that journals can be classified in two or more categories in the Web of Science. For instance, Marine Ecology Progress Series was classified in the categories of ecology, marine and freshwater biology, and oceanography, and thus the sum of the percentages was higher than 100% [36].
The top 15 most productive journals with 100 articles or more are listed in Table 3 with the journal impact factor (IF2019), number of authors per publication (APP), number of citations per publication (CPP2019), and Web of Science category. Estuarine Coastal and Shelf Science published the most articles (412 articles; 3.2% of 12,955 articles). Table 3 shows that articles published in PLoS One had the highest APP of 6.0. Articles published in Marine Ecology Progress Series had the highest CPP2019 of 41, while articles published in Indian Journal of Geo-Marine Sciences had a CPP2019 of 1.9. In addition, according to the journal impact factor, Nature, with five articles, places first with the highest IF2019 of 42.779, followed by Science with two articles (IF2019 = 41.846), and Nature Climate Change with nine articles (IF2019 = 20.893).

3.4. Publication Performances: Countries and Institutions

Thirty-four articles (0.26% of 12,955 articles) were excluded in the analysis because they did not include any author affiliation information in SCI-EXPANDED. Of the 12,921 mangrove articles from 151 different countries, 8500 articles (66% of the 12,921 articles) were single-country articles across 95 different countries, while 4421 (34%) articles were international collaborations from 147 different countries. Table 4 listed the top ten productive countries with 500 articles or more. Three American countries, three European countries, three Asian countries, and one country from Oceania were ranked in the top ten in terms of publications number. Interestingly, the number of publications was not consistent with the mangrove area coverage of the individual countries. For example, Indonesia has the world’s largest mangrove coverage and ranked 11th in publications number (TP = 210). Similarly, Australia and Brazil ranked fourth and fifth in terms of publications number, although their mangrove coverage is greater than the USA, China, or India. Outside of the top ten, South Africa, with 174 articles, ranked 22nd and was the top productive country in Africa. Six publication indicators, the total number of articles (TP), single-country articles (IP), internationally collaborative articles (CP), first-author articles (FP), corresponding-author articles (RP), and single-author articles (SP) [55], as well as their citation indicator (CPP2019) [56], were applied to compare publication performance.
The USA dominated among the three publication indicators with a TP of 2665 articles (21% of 12,921 articles), a CP of 1344 articles (30% of 4421 internationally collaborative articles), and an SP with 204 articles (21% of 964 single-author articles). China also ranked top among the three publication indicators with an IP of 1475 articles (17% of 8500 single-country articles), an FP of 1921 articles (15% of 12,921 first-author articles), and an RP of 1863 articles (15% of 12,812 corresponding-author articles). Comparing the top ten countries, the USA had the highest CPP2019 for their total articles, single-country articles, first-author articles, and corresponding-author articles with a CPP2019 of 31, 32, 32, and 32, respectively. Australia had the highest CPP2019 for their total articles, single-country articles, first-author articles, and corresponding-author articles with a CPP2019 of 31, 32, 32, and 32, respectively. Australia had the highest CPP2019 for their total articles, internationally collaborative articles, and single-author articles with a CPP2019 of 31, 33, and 40, respectively. China ranked second in TP, first in FP, third in CP, first in FP, first in RP, and seventh in SP, but in CPP2019 ranked seventh in TP, sixth in FP, 10th in CP, sixth in FP, sixth in RP, and fourth in SP. Figure 4 shows a comparison of the development among the top five productive countries in 2019 with 100 articles or more. The USA, China, India, Australia, and Brazil not only ranked the top five on total publications but also on total publications in 2019. The USA ranked top from 1990 to 2009, while China has ranked top since 2013. A sharp increase was found in China, the USA, and Australia in recent years, ranking first, second, and third in 2019, respectively.
With regard to institutions, 4273 articles (33% of 12,952 articles) were of a single institution, whereas 8648 articles (67%) were inter-institutionally collaborative. Table 5 demonstrates the characteristics of the top 20 productive institutions with 120 articles or more and six publication indicators [55] and their citation indicator CPP2019. The Chinese Academy of Sciences in China took the leading position for four publication indicators with a TP of 473 articles (3.7% of 12,952 articles), a CP of 414 articles (4.8% of 8648 inter-institutionally collaborative articles), FP with 283 articles (2.2% of 12,952 first-author articles), and an RP of 271 articles (2.1% of 12,812 corresponding-author articles). The Xiamen University in China and the Annamalai University in India took the leading position with an IP of 97 articles (2.3% of 4273 single institution articles), respectively. The Australian Institute of Marine Science in Australia ranked top with an SP of 18 articles (1.9% of 964 single-author articles). The Australian Institute of Marine Science dominated the CPP2019 for their six types of publications: TP, IP, CP, FP, RP, and SP. The National Autonomous University of Mexico had lower CPP2019 for their total articles (CPP2019 = 12), inter-institutionally collaborative articles (CPP2019 = 12), first-author articles (CPP2019 = 11), and corresponding-author articles (CPP2019 = 11). A bias appeared because the Chinese Academy of Sciences has over 100 branches in different cities [57]. At present, the publications of the institute were pooled as one heading and publications divided into branches would result in different rankings.

3.5. The Most Frequently Cited Articles and the Most Impact Articles in 2019

Highly cited publications would not always have high impact or visibility after publication [53]. The number of citations received in the most recent year of 2019 (C2019) might provide additional information for readers to understand the impact of a highly cited article today [28]. The 12,955 mangrove articles ranked differently if sorted by TC2019 than sorted by C2019. A total of 4256 articles (33% of 12,955 articles) had no citation in the most recent year (C2019 = 0), and 1343 (10%) articles had no citation from their publication year to the end of 2019 (TC2019 = 0). Furthermore, among the top 100 C2019 articles, 52% of the articles were among the top 100 TC2019 articles.
The 12,955 mangrove-related articles were searched out with search keywords in their title, abstract, and author keywords from SCI-EXPANDED in the last three decades. A total of 7495 articles (58% of 12,955 articles), 11,947 articles (94% of 12,752 articles with an abstract), and 5523 articles (53% of 10,508 articles with author keywords) contained search keywords in their title, abstract, and author keywords, respectively. The title of an article is a label that supplies reasonable details of the article’s subjects [58]. Author keywords are given by authors to offer more information about the main research focused on by articles. Articles that contain search keywords only in their abstract might not relate to the search topic directly. The ten of the top 20 articles on TC2019 contained search keywords in their abstract only. Typical examples, including articles by Waycott et al. [59], Chave et al. [60], Loarie et al. [61], and Knowlton and Weigt [62], ranked first with a TC2019 of 1535, second with a TC2019 of 1376, third with a TC2019 of 1031, and 10th with a TC2019 of 601, respectively. Citation histories of the top ten most frequently cited articles with search keywords in their title or author keywords are presented in Figure 5. An article by Giri et al. [2] ranked at the top on annual citations from 2014 to 2019 in mangrove research. Articles entitled “Mangroves among the most carbon-rich forests in the tropics” [6] with a C2019 of 171 (ranked third) had high impact in recent years.
Table 6 shows the top ten most frequently cited articles with TC2019 > 330. The top ten articles were published by 40 institutes from 16 countries. The USA published six of the top ten most frequently cited articles, followed by Australia (5 articles), Canada (2), China (2), Indonesia (2), the UK (2), and one each by Belgium, Finland, India, Japan, Kenya, Malaysia, Mexico, Philippines, Singapore, and Vietnam, respectively. The University of Queensland (Australia) published four of the top ten most frequently cited articles, followed by the Australian Institute of Marine Science (Australia) and the U.S. Geological survey (USA), which published two top ten articles, respectively. Six articles with search keywords in their title or author keywords were ranked on both the top 16 TC2019 as the most frequently cited articles and C2019 as the most impact in the most recent year articles. These six highly cited and most impactful articles among 2019 articles are summarized as followed:
i.
Status and distribution of mangrove forests of the world using earth observation satellite data [2]
This article was published by eight authors from five institutes: the U.S. Geological survey (USA), United Nations Environment Programme (Kenya), United Nations Environment Programme (USA), National Aeronautics and Space Administration (USA), and the University of Queensland (Australia) with a TC2019 of 856 (ranked fourth) and C2019 of 179 (ranked second). In the paper, the authors mapped the global distribution and status of mangroves using data from the Global Land Survey (GLS) and satellite observations. Apart from identifying the extent of mangroves, the authors also found that 75% of the world’s mangroves are located in just 15 countries, of which only about 7% are protected under the existing protected area networks (IUCN category I-IV). Using consistent and high resolution (30 m) satellite images, the authors also confirmed that the global coverage of mangroves is 12.3% less than previously thought, a large proportion of which is found between 5° N and 5° S latitude.
ii.
Present state and future of the world’s mangrove forests [1]
This article by Alongi from the Australian Institute of Marine Science with a TC2019 of 821 (ranked fifth) and a C2019 of 97 (ranked ninth) presents a comprehensive review of mangrove ecosystems, their management, and their threats. The author indicated human pressure as the major threat to mangroves worldwide, followed by urban development, aquaculture, mining, overexploitation for timber, and aquatic resources such as fish, crustaceans, and shellfish. The authors also predicted the future of mangroves until 2025 and found it to be optimistic, as the number of mangrove rehabilitation and restoration projects increased locally, with some countries expanding their area coverage of mangroves. The author concluded that after 2025, the management of mangroves will depend on technological and ecological advances such as silviculture, genetic improvements of species, and forestry modelling, although the reduction of human pressure will remain the key priority.
iii.
Mangrove forests: One of the world’s threatened major tropical environments [63]
This article was published by three authors from the Boston University (USA) with a TC2019 of 850 (ranked sixth) and a C2019 of 85 (ranked 12th). In their article, the authors estimated the global mangrove area losses from various human activities to be around 36 × 103 km2. The magnitude and relative contributions of various human activities to such losses were, however, different across continents. Overall, the percentage losses of mangrove area increased as per capita GNP increased. Mariculture, or more specifically shrimp culture, plays a significant role in reducing mangrove forest area in many tropical countries. The authors also found that, globally, the increase of mangrove forest area from restoration and natural re-growth is still negligible when compared with mangrove area losses.
iv.
Mangroves among the most carbon-rich forests in the tropics [6]
This article was published by six authors from three institutes: the USDA Forest Service (USA), Center for International Forestry Research (Indonesia), and University of Helsinki (Finland) with a TC2019 of 793 (ranked seventh) and a C2019 of 171 (ranked third), and it provides a comprehensive whole-ecosystem carbon budget of the mangrove ecosystem using data from 25 mangrove forest sites distributed across the Indo-Pacific region. In their study, the authors used 10 estuarine and 15 oceanic mangrove forest sites and found a mean carbon storage of 1074 Mg C ha−1 and 990 Mg C ha−1, respectively, in estuarine and coastal sites. The authors, based on their global assessment, found that mangroves are amongst the most carbon-rich forests in the tropics, with an average carbon density of 1023 Mg C ha−1. Their study also suggests that below-ground carbon accounts for 71–98% and 49–90% of the total storage in estuarine and oceanic sites, respectively. Below-ground carbon (stored in the top 30 cm of soil) also represents the most vulnerable pool of carbon to land-use change in mangrove ecosystems.
v.
Global carbon sequestration in tidal, saline wetland soils [15]
This article was published by four authors from four institutes: McGill University (Canada), Yale University (USA), and the U.S. Geological Survey (USA) with a TC2019 of 635 (ranked ninth) and a C2019 of 103 (ranked eighth). In their study, Chmura et al. [15] compiled data for 154 mangrove and salt marsh sites from the Atlantic and Pacific coasts, as well as the Indian Ocean, Mediterranean Sea, and Gulf of Mexico. The authors found the average soil carbon density of mangrove swamps significantly higher than salt marshes, which declines with increasing average annual temperature. They estimated the carbon sequestration by mangroves and salt marshes to be around 44.6 Tg C yr−1 globally. Carbon sequestration rates were not significantly different between mangroves and salt marshes, and variability in sediment accumulation rates was found to be a major control of carbon sequestration.
vi.
The loss of species: Mangrove extinction risk and geographic areas of global concern [65]
This article was published by 21 authors from 19 institutes: Old Dominion University (USA), Nature Conservancy (USA), University of Plymouth (the UK), the University of Queensland (Australia), Harvard University (USA), University of Tasmania (Australia), New England Wild Flower Society (USA), University of Philippines (Philippines), Annamalai University (India), Vrije University of Brussel (Belgium), Tohoku Gakuin University (Japan), University of New Hampshire (USA), Nong Lam University (Vietnam), University of Sains Malaysia (Malaysia), Southeast Asian Fisheries Development Center (Philippines), Central Luzon State University (Philippines), Indonesian Institute of Sciences (Indonesia), Shandong University (China), and Nanyang Technological University (Singapore) with a TC2019 of 428 (ranked 16th) and a C2019 of 88 (ranked 10th). In their article, the authors compiled species-specific information on global distribution, population status, life history traits, and major threats for each of the 70 true mangrove species. Each species’ probability of extinction was also assessed using the IUCN Red List of Threatened Species criteria. It was found that 11 of the 70 mangrove species are facing the risk of extinction. The Atlantic and Pacific coasts of Central America are particular areas of geographical concern, where as many as 40% of the known mangrove species are threatened with extinction.

3.6. Research Foci and Their Trends

Ho’s group proposed a distribution of words in article titles, abstracts, author keywords, and KeyWords Plus in different time periods as information to evaluate the main research foci and find their development trends in research topics [69,70]. Accordingly, we examined keywords in article titles, abstracts, author keywords, and KeyWords Plus and ranked them according to the whole study duration and 10-year study period (Supplementary Materials A, B, and C). Table 7 below represents the 25 most frequently used author keywords according to their ranking. Except for searching the keywords, mangrove and mangroves, salinity was found to be the most-frequently used author keyword (in 224 articles; 2.1% of total 10,508 articles in 1992–2019), followed by estuary (218; 2.1%), climate change (215; 2.0%), and Avicennia marina (207; 2.0%). The author keyword “blue carbon” appeared in the last decade only. Four blue carbon related mangrove articles were published in 2012, including two highly cited articles with a TC2019 of 100 or more [36]: “Seagrass ecosystems as a globally significant carbon stock” [71] with a TC2019 of 565 (rank 11th) and a C2019 of 116 (rank seventh) and “Estimating global “blue carbon” emissions from conversion and degradation of vegetated coastal ecosystems” [72] with a TC2019 of 462 (rank 12th) and a C2019 of 120 (rank sixth). Quite interestingly, remote sensing emerged as a popular keyword used in mangrove-related studies in recent years and is positioned immediately after mangroves. In 2011, a remote sensing article by Giri et al. [2] had a TC2019 of 856 (rank fourth) and a C2019 of 179 (rank second). Our findings are also coherent with the findings reported in Sharma [73].
The results of our keyword analyses provide information about the main and possible research foci based on word cluster analysis, where a serious synonymic single word and the congeneric phrases from the results of words analysis were summed up, which could represent the possible research hotspots related to a field [74]. Each word cluster is composed of several supporting words [21]. Thus, the five possible main research foci related to mangroves are Rhizophora, climate change, remote sensing, biodiversity, and blue carbon. Figure 6 shows the development trends of research on these topics.
Rhizophora (with supporting words: Rhizophora mangle, Rhizophoraceae, and Rhizophorae) emerged in our word cluster analysis and author keyword search both as Rhizophora mangle (12th position, TP = 150) and Rhizophora (24th position, TP 106). Rhizophora appeared also in our words in title (27th position, TP = 370) as well as abstract (30th position, TP = 1459) searches. Rhizophora represents a major genus of true mangroves and mangrove trees. The most notable species of Rhizophora is–Rhizophora mangle, also known as red mangrove [8]. Many species of Rhizophora can easily grow and be dispersed by water. Therefore, they are commonly used for mangrove restoration and vertical expansion of estuarine mangrove ecosystems throughout the tropics and sub-tropics [8].
Climate change (and climate changes) emerged in our word cluster analysis (Figure 6) and in the top 25 in author keywords (fifth position, TP 215) and the KeyWords Plus (13th position, TP 378) searches. Climate change is a global phenomenon, and it is affecting mangroves in many ways [75]. Climate change and the resulting sea-level rise are likely to affect the aerial extent of mangroves and species diversity [18]. Climate change will also cause more frequent catastrophic events such as cyclones (synonymous with hurricanes and typhoons), tidal surges, and floods, affecting mangrove forests globally [4]. In recent years, mangroves are also recognized for their potential role in climate change mitigation, as they store more carbon than any other terrestrial ecosystems [6].
Remote sensing, as already mentioned, has been gaining increasing attention from mangrove researchers in recent years, although there is evidence of past research too (Figure 6). Remote sensing (with supporting words: remote sensed and landsat) emerged in our word cluster analysis and in the top 25 in the author keywords (seventh position, TP = 198) search. With the advancement of science and easy access to satellite imagery, remote sensing is progressively becoming a new tool for monitoring changes in mangroves and vegetation dynamics such as changes in species composition, forest structure, area, etc. [16,76]. As ground-based surveys in mangrove forests are often difficult, costly, and time-consuming, remote sensing also offers scientists an alternative way to study mangroves, the temporal change effects of catastrophic events on mangrove forests, etc. [2,76].
Biodiversity (with supporting words: biodiversidad and biodiversities) appeared both in our word cluster analysis and in the top 25 in the author keywords (13th position, TP = 148) search. Other keywords, such as diversity and conservation, found in our author keywords and KeyWords Plus searches may also be related to biodiversity. Mangroves are recognized for their exceptionally high biodiversity, both terrestrial and aquatic [8,64]. The aquatic (including marine) biodiversity of mangroves is a major source of livelihood and protein in tropical developing countries [9]. Because of their position in the interface between coastal and terrestrial ecosystems, mangroves provide a wide array of habitats to wildlife and encompass a self-sustaining food web that includes large and small mammals, birds, reptiles, insects, fishes, and crustaceans such as crabs and shrimps [75]. Mangrove biodiversity is also on the verge of extinction due to overexploitation, unplanned coastal development, climate change and the resulting sea-level rise, etc. [10,18].
Blue carbon (with supporting words: blue carbon ecosystem, blue carbon sinks, blue carbon stocks, coastal blue carbon, and blue carbon emissions) emerged both in our word cluster analysis and in the top 25 in the author keywords (19th position, TP = 117) search, although it appeared in mangrove-related articles only in the last decade. “Blue carbon” is still an emerging concept, and it is the term used for carbon captured by coastal and ocean ecosystems, mostly mangroves, salt marshes, seagrasses, and macroalgae [72]. As already mentioned, mangroves can absorb carbon from the atmosphere as much as 40 × faster than terrestrial ecosystems. Therefore, they are widely promoted as a cost-effective climate change mitigation measure [13,14,17]. Besides climate change mitigation, blue carbon also offers livelihood and economic opportunities for coastal communities, including climate change adaptation [10].

4. Conclusions

Mangroves are increasingly recognized for their diverse social, environmental, and economic benefits. They also provide essential ecosystem services, so significant losses of mangrove forests will have important consequences. Our bibliometric study has brought together the knowledge on publications related to mangroves and mangrove forests that are available from the Web of Science database from the period of 1990 to 2019. We performed Science Citation Index Expanded (SCI-EXPANDED) analysis of 12,955 publications to visualize publication patterns that include the most prominent authors, institutions, countries, research categories, and journals. A total of 93% of the published documents were articles, followed by proceedings papers (4.6%). When considering the most productive Web of Science subject category, the majority of the articles that were found belong to marine and freshwater biology, followed by environmental sciences, ecology, oceanography, and plant sciences. The USA and China were the leading countries in ranking, according to the number of publications on mangroves. The articles published by the USA and Australia, however, had higher impact in the research.
We also identified the most impactful articles on mangrove forests by using updated citation parameters, where instead of relying only on total citations, we also considered recent citations. Research hotspots on the basis of our bibliometric study were identified, especially after analyzing words in author keywords, article titles, abstracts, and KeyWords Plus. Leading articles and institutions working on mangroves were also identified. These indicators are intended to facilitate researchers in the analysis of existing literature, which could improve the research direction for better scientific contribution. Our bibliometric study also identified emerging fields of research, researchers, and institutions useful in facilitating potential venues for future research, collaboration, and knowledge exchange on mangrove forests.

Supplementary Materials

The following are available online at https://www.mdpi.com/article/10.3390/su132212532/s1.

Author Contributions

Conceptualization, Y.-S.H. and S.A.M.; methodology, Y.-S.H.; formal analysis, Y.-S.H. and S.A.M.; data curation, Y.-S.H.; writing—original draft preparation, Y.-S.H. and S.A.M.; writing—review and editing, Y.-S.H. and S.A.M.; funding acquisition, S.A.M. All authors have read and agreed to the published version of the manuscript.

Funding

Sharif A. Mukul was supported by a grant (BES LRB20-1006) from the British Ecological Society (UK) and the Centre for Research on Land-use Sustainability (Bangladesh) to facilitate the writing.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

We thank William F. Laurance (James Cook University, Australia) for his comments on an abridged version of this manuscript.

Conflicts of Interest

The authors declare no conflict of interest. The views and interpretations in this publication are those of the author’s and they are not necessarily attributable to their organizations.

References

  1. Alongi, D.M. Present state and future of the world’s mangrove forests. Environ. Conserv. 2002, 29, 331–349. [Google Scholar] [CrossRef] [Green Version]
  2. Giri, C.; Ochieng, E.; Tieszen, L.L.; Zhu, Z.; Singh, A.; Loveland, T.; Masek, J.; Duke, N. Status and distribution of mangrove forests of the world using earth observation satellite data. Glob. Ecol. Biogeogr. 2011, 20, 154–159. [Google Scholar] [CrossRef]
  3. Costanza, R.; Pérez-Maqueo, O.; Martinez, M.L.; Sutton, P.; Anderson, S.J.; Mulder, K. The value of coastal wetlands for hurricane protection. Ambio 2008, 37, 241–248. [Google Scholar] [CrossRef]
  4. Romañach, S.S.; DeAngelis, D.L.; Koh, H.L.; Li, Y.; Teh, S.Y.; Barizan, R.S.R.; Zhai, L. Conservation and restoration of mangroves: Global status, perspectives, and prognosis. Ocean Coast. Manag. 2018, 154, 72–82. [Google Scholar] [CrossRef]
  5. Halder, N.K.; Merchant, A.; Misbahuzzaman, K.; Wagner, S.; Mukul, S.A. Why some trees are more vulnerable during catastrophic cyclone events in the Sundarbans mangrove forest of Bangladesh? For. Ecol. Manag. 2021, 488, 119117. [Google Scholar] [CrossRef]
  6. Donato, D.C.; Kauffman, J.B.; Murdiyarso, D.; Kurnianto, S.; Stidham, M.; Kanninen, M. Mangroves among the most carbon-rich forests in the tropics. Nat. Geosci. 2011, 4, 293–297. [Google Scholar] [CrossRef]
  7. Duke, N.C.; Meynecke, J.O.; Dittmann, S.; Ellison, A.M.; Anger, K.; Berger, U.; Cannicci, S.; Diele, K.; Ewel, K.C.; Field, C.D.; et al. A world without mangroves? Science 2007, 317, 41–42. [Google Scholar] [CrossRef] [Green Version]
  8. Spalding, M.; Kainuma, M. Collins L Word Atlas of Mangroves; Earthscan: London, UK, 2010. [Google Scholar]
  9. Uddin, M.S.; van Steveninck, E.R.; Stuip, M.; Shah, M.A.R. Economic valuation of provisioning and cultural services of a protected mangrove ecosystem: A case study on Sundarbans Reserve Forest, Bangladesh. Ecosyst. Serv. 2013, 5, e88–e93. [Google Scholar] [CrossRef]
  10. Friess, D.A.; Rogers, K.; Lovelock, C.E.; Krauss, K.W.; Hamilton, S.E.; Lee, S.Y.; Lucas, R.; Primavera, J.; Rajkaran, A.; Shi, S. The state of the world’s mangrove forests: Past, present, and future. Annu. Rev. Env. Resour. 2019, 44, 89–115. [Google Scholar] [CrossRef] [Green Version]
  11. Menéndez, P.; Losada, I.J.; Torres-Ortega, S.; Narayan, S.; Beck, M.W. The global flood protection benefits of mangroves. Sci. Rep. 2020, 10, 4404. [Google Scholar] [CrossRef] [PubMed]
  12. Sun, F.; Carson, R.T. Coastal wetlands reduce property damage during tropical cyclones. Proc. Natl. Acad. Sci. USA 2020, 117, 5719–5725. [Google Scholar] [CrossRef] [PubMed]
  13. Alongi, D.M. Carbon cycling and storage in mangrove forests. Annu. Rev. Mar. Sci. 2014, 6, 195–219. [Google Scholar] [CrossRef] [PubMed]
  14. Mukul, S.A.; Halim, M.A.; Herbohn, J. Forest Carbon Stock and Fluxes: Distribution, Biogeochemical Cycles, and Measurement Techniques. In Life on Land, Encyclopedia of the UN Sustainable Development Goals; Leal Filho, W., Azul, A., Brandli, L., Lange Salvia, A., Wall, T., Eds.; Springer: Cham, Switzerland, 2021; pp. 365–380. [Google Scholar] [CrossRef]
  15. Chmura, G.L.; Anisfeld, S.C.; Cahoon, D.R.; Lynch, J.C. Global carbon sequestration in tidal, saline wetland soils. Glob. Biogeochem. Cycle 2003, 17, 1111. [Google Scholar] [CrossRef]
  16. Thomas, N.; Lucas, R.; Bunting, P.; Hardy, A.; Rosenqvist, A.; Simard, M. Distribution and drivers of global mangrove forest change, 1996–2010. PLoS ONE 2017, 12, e0179302. [Google Scholar] [CrossRef] [Green Version]
  17. Hamilton, S.E.; Friess, D.A. Global carbon stocks and potential emissions due to mangrove deforestation from 2000 to 2012. Nat. Clim. Change 2018, 8, 240–244. [Google Scholar] [CrossRef] [Green Version]
  18. Mukul, S.A.; Alamgir, M.; Sohel, M.S.I.; Pert, P.L.; Turton, S.M.; Herbohn, J.; Khan, M.S.I.; Ali Reza, A.H.M.; Munim, S.A.; Laurance, W.F. Combined effects of climate change and sea-level rise project dramatic habitat loss of the globally endangered Bengal tiger in the Bangladesh Sundarbans. Sci. Total Environ. 2019, 663, 830–840. [Google Scholar] [CrossRef]
  19. Mao, N.; Wang, M.H.; Ho, Y.S. A bibliometric study of the trend in articles related to risk assessment published in Science Citation Index. Hum. Ecol. Risk Assess. 2010, 16, 801–824. [Google Scholar] [CrossRef]
  20. Fu, H.Z.; Ho, Y.S. Top cited articles in thermodynamic research. J. Eng. Thermophys. 2015, 24, 68–85. [Google Scholar] [CrossRef]
  21. Usman, M.; Ho, Y.S. A bibliometric study of the Fenton oxidation for soil and water remediation. J. Environ. Manag. 2020, 270, 110886. [Google Scholar] [CrossRef] [PubMed]
  22. Ho, Y.S. Comments on “Mapping the scientific research on non-point source pollution: A bibliometric analysis” by Yang et al. (2017). Environ. Sci. Pollut. Res. 2018, 25, 30737–30738. [Google Scholar] [CrossRef] [PubMed]
  23. Ho, Y.S. A comparison of new analysis results and the results in ‘Research trends in proton exchange membrane fuel cells during 2008–2018: A bibliometric analysis’ by Yonoff et al. Heliyon 2020, 6, e04848. [Google Scholar] [CrossRef]
  24. Fu, H.Z.; Wang, M.H.; Ho, Y.S. The most frequently cited adsorption research articles in the Science Citation Index (Expanded). J. Colloid Interf. Sci. 2012, 379, 148–156. [Google Scholar] [CrossRef]
  25. Ho, Y.S. Some comments on: Mao et al. (2018) “Bibliometric analysis of insights into soil remediation” Journal of Soils and Sediments, 18(7): 2520–2534. J. Soils Sediments 2019, 19, 3657–3658. [Google Scholar] [CrossRef]
  26. Ho, Y.S. Rebuttal to: Ma et al. “Past, current, and future research on microalga-derived biodiesel: A critical review and bibliometric analysis”, vol. 25, pp. 10596–10610. Environ. Sci. Pollut. Res. 2020, 27, 7742–7743. [Google Scholar] [CrossRef]
  27. Garfield, E. KeyWords Plus: ISI’s breakthrough retrieval method. Part 1. Expanding your searching power on Current Contents on Diskette. Curr. Contents 1990, 32, 5–9. [Google Scholar]
  28. Ho, Y.S. Top-cited articles in chemical engineering in Science Citation Index Expanded: A bibliometric analysis. Chin. J. Chem. Eng. 2012, 20, 478–488. [Google Scholar] [CrossRef]
  29. Ho, Y.S. Classic articles on social work field in Social Science Citation Index: A bibliometric analysis. Scientometrics 2014, 98, 137–155. [Google Scholar] [CrossRef]
  30. Chuang, K.Y.; Wang, M.H.; Ho, Y.S. High-impact papers presented in the subject category of water resources in the Essential Science Indicators database of the Institute for Scientific Information. Scientometrics 2011, 87, 551–562. [Google Scholar] [CrossRef]
  31. Monge-Nájera, J.; Ho, Y.S. Bibliometry of Panama publications in the Science Citation Index Expanded: Publication type, language, fields, authors and institutions. Rev. Biol. Trop. 2015, 63, 1255–1266. [Google Scholar] [CrossRef] [Green Version]
  32. Monge-Nájera, J.; Mêgnigbêto, E.; Ho, Y.S. Research impact and productivity of Benin according to the Science Citation Index Expanded (1973 to 2018). Rev. Biol. Trop. 2020, 68, 909–918. [Google Scholar] [CrossRef]
  33. Tchuifon, D.R.; Fu, H.Z.; Ho, Y.S. Cameroon publications in the Science Citation Index Expanded: Bibliometric analysis. Rev. Biol. Trop. 2017, 65, 1582–1591. [Google Scholar] [CrossRef] [Green Version]
  34. Ho, Y.S.; Siu, E.; Chuang, K.Y. A bibliometric analysis of dengue-related publications in the Science Citation Index Expanded. Future Virol. 2016, 11, 631–648. [Google Scholar] [CrossRef] [Green Version]
  35. Lin, C.L.; Ho, Y.S. A bibliometric analysis of publications on pluripotent stem cell research. Cell J. 2015, 17, 59–70. [Google Scholar] [CrossRef]
  36. Ho, Y.S. A bibliometric analysis of highly cited articles in materials science. Curr. Sci. 2014, 107, 1565–1572. [Google Scholar]
  37. Wang, M.H.; Fu, H.Z.; Ho, Y.S. Comparison of universities’ scientific performance using bibliometric indicators. Malays. J. Libr. Sci. 2011, 16, 1–19. Available online: https://ejournal.um.edu.my/index.php/MJLIS/article/view/6693 (accessed on 5 June 2021).
  38. Erwin, K.L. Wetlands and global climate change: The role of wetland restoration in a changing world. Wetl. Ecol. Manag. 2009, 17, 71–84. [Google Scholar] [CrossRef]
  39. Hsieh, W.H.; Chiu, W.T.; Lee, Y.S.; Ho, Y.S. Bibliometric analysis of patent ductus arteriosus treatments. Scientometrics 2004, 60, 205–215. [Google Scholar] [CrossRef]
  40. Ho, H.C.; Ho, Y.S. Publications in dance field in Arts & Humanities Citation Index: A bibliometric analysis. Scientometrics 2015, 105, 1031–1040. [Google Scholar] [CrossRef]
  41. Monge-Nájera, J.; Ho, Y.S. El Salvador publications in the Science Citation Index Expanded: Subjects, authorship, collaboration and citation patterns. Rev. Biol. Trop. 2017, 65, 1428–1436. [Google Scholar] [CrossRef] [Green Version]
  42. Balasubramanian, V.; Sie, M.; Hijmans, R.J.; Otsuka, K. Increasing rice production in Sub-Saharan Africa: Challenges and opportunities. Adv. Agron. 2007, 94, 55–133. [Google Scholar] [CrossRef]
  43. Feller, I.C.; Lovelock, C.E.; Berger, U.; McKee, K.L.; Joye, S.B.; Ball, M.C. Biocomplexity in mangrove ecosystems. Annu. Rev. Mar. Sci. 2010, 2, 395–417. [Google Scholar] [CrossRef] [Green Version]
  44. Thiel, M.; Haye, P.A. The ecology of rafting in the marine environment. III. Biogeographical and evolutionary consequences. Oceanogr. Mar. Biol. 2006, 44, 323–429. [Google Scholar] [CrossRef]
  45. Manson, F.J.; Loneragan, N.R.; Skilleter, G.A.; Phinn, S.R. An evaluation of the evidence for linkages between mangroves and fisheries: A synthesis of the literature and identification of research directions. Oceanogr. Mar. Biol. 2005, 43, 483–513. [Google Scholar]
  46. Armisen, D.; Rajakumar, R.; Friedrich, M.; Benoit, J.B.; Robertson, H.M.; Panfilio, K.A.; Ahn, S.J.; Poelchau, M.F.; Chao, H.; Dinh, H.; et al. The genome of the water strider Gerris buenoi reveals expansions of gene repertoires associated with adaptations to life on the water. BMC Genom. 2018, 19, 832. [Google Scholar] [CrossRef] [PubMed]
  47. Wang, M.H.; Ho, Y.S. Research articles and publication trends in environmental sciences from 1998 to 2009. Arch. Environ. Sci. 2011, 5, 1–10. [Google Scholar]
  48. Ho, Y.S. The top-cited research works in the Science Citation Index Expanded. Scientometrics 2013, 94, 1297–1312. [Google Scholar] [CrossRef]
  49. Zhang, D.; Fu, H.Z.; Ho, Y.S. Characteristics and trends on global environmental monitoring research: A bibliometric analysis based on Science Citation Index Expanded. Environ. Sci. Pollut. Res. 2017, 24, 26079–26091. [Google Scholar] [CrossRef]
  50. Mo, Z.W.; Fu, H.Z.; Ho, Y.S. Global development and trend of wind tunnel research from 1991 to 2014: A bibliometric analysis. Environ. Sci. Pollut. Res. 2018, 25, 30257–30270. [Google Scholar] [CrossRef]
  51. Lei, J.; Fu, H.Z.; Ho, Y.S. A global perspective of bioaccumulation research using bibliometric analysis. COLLNET J. Scientometr. Inf. Manag. 2018, 12, 327–341. [Google Scholar] [CrossRef]
  52. Ho, Y.S.; Fu, H.Z. Mapping of metal-organic frameworks publications: A bibliometric analysis. Inorg. Chem. Commun. 2016, 73, 174–182. [Google Scholar] [CrossRef]
  53. Ho, Y.S.; Kahn, M. A bibliometric study of highly cited reviews in the Science Citation Index Expanded™. J. Assoc. Inf. Sci. Technol. 2014, 65, 372–385. [Google Scholar] [CrossRef]
  54. Ho, Y.S.; Satoh, H.; Lin, S.Y. Japanese lung cancer research trends and performance in Science Citation Index. Intern. Med. 2010, 49, 2219–2228. [Google Scholar] [CrossRef] [Green Version]
  55. Hsu, Y.H.E.; Ho, Y.S. Highly cited articles in health care sciences and services field in Science Citation Index Expanded: A bibliometric analysis for 1958–2012. Methods Inf. Med. 2014, 53, 446–458. [Google Scholar] [CrossRef]
  56. Ho, Y.S.; Lim, L.B.L.; Monge-Nájera, J. Brunei publications in the Science Citation Index Expanded (1973–2016): Bibliometrics and comparison with other tropical countries. Rev. Biol. Trop. 2018, 66, 1090–1100. [Google Scholar] [CrossRef] [Green Version]
  57. Li, J.F.; Zhang, Y.H.; Wang, X.S.; Ho, Y.S. Bibliometric analysis of atmospheric simulation trends in meteorology and atmospheric science journals. Croat. Chem. Acta 2009, 82, 695–705. [Google Scholar] [CrossRef]
  58. Wang, M.H.; Yu, T.C.; Ho, Y.S. A bibliometric analysis of the performance of Water Research. Scientometrics 2010, 84, 813–820. [Google Scholar] [CrossRef]
  59. Waycott, M.; Duarte, C.M.; Carruthers, T.J.B.; Orth, R.J.; Dennison, W.C.; Olyarnik, S.; Calladine, A.; Fourqurean, J.W.; Heck, K.L.; Hughes, A.R.; et al. Accelerating loss of seagrasses across the globe threatens coastal ecosystems. Proc. Natl. Acad. Sci. USA 2009, 106, 12377–12381. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  60. Chave, J.; Andalo, C.; Brown, S.; Cairns, M.A.; Chambers, J.Q.; Eamus, D.; Fölster, H.; Fromard, F.; Higuchi, N.; Kira, T.; et al. Tree allometry and improved estimation of carbon stocks and balance in tropical forests. Oecologia 2005, 145, 87–99. [Google Scholar] [CrossRef]
  61. Loarie, S.R.; Duffy, P.B.; Hamilton, H.; Asner, G.P.; Field, C.B.; Ackerly, D.D. The velocity of climate change. Nature 2009, 462, 1052–1055. [Google Scholar] [CrossRef] [PubMed]
  62. Knowlton, N.; Weigt, L.A. New dates and new rates for divergence across the Isthmus of Panama. Proc. Royal Soc. B Biol. Sci. 1998, 265, 2257–2263. [Google Scholar] [CrossRef] [Green Version]
  63. Valiela, I.; Bowen, J.L.; York, J.K. Mangrove forests: One of the world’s threatened major tropical environments. Bioscience 2001, 51, 807–815. [Google Scholar] [CrossRef] [Green Version]
  64. Mumby, P.J.; Edwards, A.J.; Rias-Gonzalez, J.E.; Lindeman, K.C.; Blackwell, P.G.; Gall, A.; Gorczynska, M.I.; Harborne, A.R.; Pescod, C.L.; Renken, H.; et al. Mangroves enhance the biomass of coral reef fish communities in the Caribbean. Nature 2004, 427, 533–536. [Google Scholar] [CrossRef] [Green Version]
  65. Polidoro, B.A.; Carpenter, K.E.; Collins, L.; Duke, N.C.; Ellison, A.M.; Ellison, J.C.; Farnsworth, E.J.; Fernando, E.S.; Kathiresan, K.; Koedam, N.E.; et al. The loss of species: Mangrove extinction risk and geographic areas of global concern. PLoS ONE 2010, 5, e10095. [Google Scholar] [CrossRef] [PubMed]
  66. Tam, N.F.Y.; Wong, Y.S. Spatial variation of heavy metals in surface sediments of Hong Kong mangrove swamps. Environ. Pollut. 2000, 110, 195–205. [Google Scholar] [CrossRef]
  67. Duke, N.C.; Ball, M.C.; Ellison, J.C. Factors influencing biodiversity and distributional gradients in mangroves. Glob. Ecol. Biogeogr. Let. 1998, 7, 27–47. [Google Scholar] [CrossRef] [Green Version]
  68. Laegdsgaard, P.; Johnson, C. Why do juvenile fish utilise mangrove habitats? J. Exp. Mar. Biol. Ecol. 2001, 257, 229–253. [Google Scholar] [CrossRef] [Green Version]
  69. Xie, S.D.; Zhang, J.; Ho, Y.S. Assessment of world aerosol research trends by bibliometric analysis. Scientometrics 2008, 77, 113–130. [Google Scholar] [CrossRef]
  70. Wang, C.C.; Ho, Y.S. Research trend of metal-organic frameworks: A bibliometric analysis. Scientometrics 2016, 109, 481–513. [Google Scholar] [CrossRef]
  71. Fourqurean, J.W.; Duarte, C.M.; Kennedy, H.; Marba, N.; Holmer, M.; Mateo, M.A.; Apostolaki, E.T.; Kendrick, G.A.; Krause-Jensen, D.; McGlathery, K.J.; et al. Seagrass ecosystems as a globally significant carbon stock. Nat. Geosci. 2012, 5, 505–509. [Google Scholar] [CrossRef]
  72. Pendleton, L.; Donato, D.C.; Murray, B.C.; Crooks, S.; Jenkins, W.A.; Sifleet, S.; Craft, C.; Fourqurean, J.W.; Kauffman, J.B.; Marba, N.; et al. Estimating global “blue carbon” emissions from conversion and degradation of vegetated coastal ecosystems. PLoS ONE 2012, 7, e43542. [Google Scholar] [CrossRef] [Green Version]
  73. Sharma, S. Mangrove Ecosystem Research—Where Has the Focus Been So Far. In Mangrove Ecosystem Ecology and Function; Sharma, S., Ed.; IntechOpen: London, UK, 2018. [Google Scholar] [CrossRef] [Green Version]
  74. Fu, H.Z.; Wang, M.H.; Ho, Y.S. Mapping of drinking water research: A bibliometric analysis of research output during 1992–2011. Sci. Total Environ. 2013, 443, 757–765. [Google Scholar] [CrossRef] [PubMed]
  75. Biswas, P.L.; Biswas, S.R. Mangrove Forests: Ecology, Management, and Threats. In Life on Land, Encyclopedia of the UN Sustainable Development Goals; Leal Filho, W., Azul, A., Brandli, L., Lange Salvia, A., Wall, T., Eds.; Springer: Cham, Switzerland, 2021; pp. 535–648. [Google Scholar] [CrossRef]
  76. Hamilton, S.E.; Casey, D. Creation of a high spatio-temporal resolution global database of continuous mangrove forest cover for the 21st century (CGMFC-21). Glob. Ecol. Biogeogr. 2016, 25, 729–738. [Google Scholar] [CrossRef]
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Figure 1. Map showing the global distribution of mangroves (in black). Source: UNEP-WCMC (https://data.unep-wcmc.org; accessed: 15 June 2021).
Figure 1. Map showing the global distribution of mangroves (in black). Source: UNEP-WCMC (https://data.unep-wcmc.org; accessed: 15 June 2021).
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Figure 2. Number of articles and citations per publication by year.
Figure 2. Number of articles and citations per publication by year.
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Figure 3. Developments of the top six Web of Science categories in 2019.
Figure 3. Developments of the top six Web of Science categories in 2019.
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Figure 4. Comparison of development trends among the top five productive countries in 2019.
Figure 4. Comparison of development trends among the top five productive countries in 2019.
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Figure 5. The citation life of the top ten most frequently cited articles with TC2019 > 330.
Figure 5. The citation life of the top ten most frequently cited articles with TC2019 > 330.
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Figure 6. Development trends of the five main research foci of mangroves.
Figure 6. Development trends of the five main research foci of mangroves.
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Table
Table 1. Citations and authors according to document type.
Table 1. Citations and authors according to document type.
Document TypeTP%AUAPPTC2019CPP2019
Article12,9529355,7734.3258,55520
Proceedings paper6424.621943.418,65529
Review4503.218484.129,97467
Meeting abstract1951.47043.6370.19
Editorial material1080.802962.79938.9
Note640.461412.274512
Correction620.453195.1490.79
Letter420.301222.983120
News item100.20181.8391.4
Book chapter150.11815.4126484
Data paper40.029287.0112.8
Retraction30.022196.310.33
Addition correction20.01431.510.50
Book review20.01421.021.0
Biographical item10.007266.000
Discussion10.007244.01212
TP: number of publications; AU: number of authors; APP: number of authors per publication; TC2019: the total number of citations from the Web of Science Core Collection since publication year to the end of 2019; CPP2019: number of citations (TC2019) per publication (TP).
Table
Table 2. The top ten productive Web of Science categories with TP > 500.
Table 2. The top ten productive Web of Science categories with TP > 500.
Web of Science CategoryTP (%)No. JCPP2019APP
Marine and freshwater biology3140 (24)106233.8
Environmental sciences2762 (21)265214.5
Ecology1823 (14)168284.1
Oceanography1596 (12)66263.8
Plant sciences1210 (9.3)234204.2
Multidisciplinary geosciences938 (7.2)200244.3
Zoology755 (5.8)168103.1
Water resources619 (4.8)94164.1
Physical geography536 (4.1)50244.2
Multidisciplinary sciences534 (4.1)71245.2
TP: number of publications; No. J: number of journals in a Web of Science category; CPP2019: number of citations (CPP2019) per publication (TP); APP: number of authors per publication.
Table
Table 3. The top 15 productive journals with TP > 100.
Table 3. The top 15 productive journals with TP > 100.
JournalTP (%)IF2019APPCPP2019Web of Science Category
Estuarine Coastal and Shelf Science412 (3.2)2.3333.932Marine and freshwater biology
Oceanography
Marine Pollution Bulletin315 (2.4)4.0494.824Environmental science
Marine and freshwater biology
Hydrobiologia276 (2.1)2.3853.024Marine and freshwater biology
Marine Ecology Progress Series240 (1.9)2.3264.041Ecology
Marine and freshwater biology
Oceanography
Journal of Coastal Research226 (1.7)0.7933.713Environmental sciences
Physical geography
Multidisciplinary geosciences
PLoS One157 (1.2)2.7406.024Multidisciplinary sciences
Revista De Biologia Tropical153 (1.2)0.4463.16.2Biology
Ocean & Coastal Management148 (1.1)2.4823.817Oceanography
Water resources
International Journal of Systematic and Evolutionary Microbiology131 (1.0)2.4155.812Microbiology
Journal of Experimental Marine Biology and Ecology130 (1.0)2.2473.130Ecology
Marine and freshwater biology
Aquatic Botany115 (0.89)1.7103.829Plant sciences
Marine and freshwater biology
Bulletin of Marine Science115 (0.89)1.4323.425Marine and freshwater biology
Oceanography
Wetlands Ecology and Management115 (0.89)1.2214.017Environmental sciences
Water resources
Estuaries and Coasts111 (0.86)2.3194.016Environmental sciences
Marine and freshwater biology
Indian Journal of Geo-Marine Sciences104 (0.80)0.3283.71.9Oceanography
TP: number of publications; IF2019: journal impact factor in 2019; APP: number of authors per publication; CPP2019: number of citations (TC2019) per publication (TP).
Table
Table 4. Top ten productive countries with TP > 500.
Table 4. Top ten productive countries with TP > 500.
CountryTPTPIPCPFPRPSP
R (%)CPP2019R (%)CPP2019R (%)CPP2019R (%)CPP2019R (%)CPP2019R (%)CPP2019
USA26651 (21)312 (16)321 (30)302 (14)322 (14)321 (21)37
China21182 (16)171 (17)163 (15)181 (15)161 (15)167 (2.8)28
India14903 (12)143 (14)128 (7.2)203 (10)133 (10)133 (6.1)13
Australia14664 (11)315 (9.1)302 (16)335 (8.3)315 (8.4)312 (16)40
Brazil13355 (10)154 (10)116 (10)214 (8.9)124 (8.8)128 (2.7)12
Japan7076 (5.5)196 (3.2)147 (10)226 (3.9)166 (3.9)1612 (2.2)13
Germany6987 (5.4)2510 (1.7)275 (13)258 (2.8)248 (2.9)245 (3.1)21
UK6968 (5.4)2611 (1.4)264 (13)259 (2.6)299 (2.6)284 (4.5)26
Mexico5289 (4.1)167 (3.1)1213 (6.0)207 (2.9)147 (2.9)1319 (1.2)28
France50210 (3.9)259 (2.2)2210 (7.1)2711 (2.5)2410 (2.5)245 (3.1)10
TP: total number of articles; TPR (%): rank of total number of articles and percentage; IPR (%): rank of single-country articles and percentage in all single-country articles; CPR (%): rank of internationally collaborative articles and percentage in all internationally collaborative articles; FPR (%): rank of first-author articles and percentage in all first-author articles; RPR (%): rank of corresponding-author articles and percentage in all corresponding-author articles; SPR (%): rank of single-author articles and percentage in all single-author articles; CPP2019: number of citations (TC2019) per publication (TP); N/A: not available.
Table
Table 5. Top 20 productive institutions (TP > 120).
Table 5. Top 20 productive institutions (TP > 120).
Institute (Country)TPTPR (%)TP CPPIPR (%)IP PPCPR (%)CP CPPFPR (%)FP CPPRPR (%)RP CPPSPR (%)SP CPP
Chinese Academy of Sciences
(China)		4731 (3.7)183 (1.4)201 (4.8)181 (2.2)191 (2.1)1987 (0.21)3.0
Sun Yat Sen University
(China)		3182 (2.5)153 (1.4)202 (3.0)142 (1.8)153 (1.6)16N/AN/A
Xiamen University
(China)		3073 (2.4)151 (2.3)134 (2.4)163 (1.8)142 (1.8)14156 (0.10)3.0
University of Sao Paulo
(Brazil)		2484 (1.9)1426 (0.56)9.33 (2.6)158 (0.81)136 (0.86)1347 (0.31)6.7
University of Queensland
(Australia)		2265 (1.7)3618 (0.66)325 (2.3)377 (0.83)367 (0.84)3614 (0.83)26
City University of Hong Kong
(China)		2056 (1.6)348 (1.0)447 (1.9)325 (0.89)414 (1.0)3887 (0.21)33
National University
of Singapore (Singapore)		1867 (1.4)215 (1.4)2610 (1.5)206 (0.85)238 (0.84)213 (1.2)11
U.S. Geological Survey
(USA)		1848 (1.4)4745 (0.40)276 (1.9)4918 (0.58)5415 (0.61)5347 (0.31)64
Florida International
University (USA)		1839 (1.4)4414 (0.82)518 (1.7)4212 (0.65)4314 (0.62)4428 (0.41)33
Annamalai University
(India)		17010 (1.3)201 (2.3)1832 (0.84)224 (0.97)175 (0.94)189 (0.93)24
University of Malaya
(Malaysia)		16611 (1.3)167 (1.2)1612 (1.3)1710 (0.73)1311 (0.7)1347 (0.31)29
National Autonomous
University of Mexico (Mexico)		16611 (1.3)1216 (0.70)149 (1.6)1212 (0.65)1112 (0.67)1128 (0.41)23
Griffith University
(Australia)		15513 (1.2)2919 (0.63)3510 (1.5)2815 (0.60)3315 (0.61)3414 (0.83)75
University of Hong Kong
(China)		14914 (1.2)2611 (1.0)2914 (1.2)2414 (0.64)2713 (0.66)272 (1.7)33
Australian Institute of Marine
Science (Australia)		14914 (1.2)576 (1.3)6720 (1.1)5211 (0.71)609 (0.74)601 (1.9)102
University of Calcutta
(India)		14616 (1.1)1613 (0.87)1913 (1.3)159 (0.73)1710 (0.73)17N/AN/A
University of Ryukyus
(Japan)		13017 (1.0)1719 (0.63)2016 (1.2)1624 (0.45)1820 (0.48)17N/AN/A
James Cook University
(Australia)		12418 (1.0)3339 (0.42)1515 (1.2)3627 (0.42)4826 (0.42)4828 (0.41)19
Ocean University of China
(China)		12319 (0.95)1717 (0.68)2624 (1.1)1416 (0.59)1719 (0.50)17N/AN/A
Federal University of Parana
(Brazil)		12120 (0.93)1521 (0.61)1220 (1.1)1616 (0.59)1317 (0.56)14N/AN/A
TP: total number of articles; TPR (%): rank of total number of articles and percentage; IPR (%): rank of single-institute articles and percentage in all single-institute articles; CPR (%): rank of inter-institutionally collaborative articles and percentage in all inter-institutionally collaborative articles; FPR (%): rank of first-author articles and percentage in all first-author articles; RPR (%): rank of corresponding-author articles and percentage in all corresponding-author articles; SPR (%): rank of single-author articles and percentage in all single-author articles; CPP: number of citations (TC2019) per publication (TP); N/A: not available.
Table
Table 6. The top ten most frequently cited articles with TC2019 > 330.
Table 6. The top ten most frequently cited articles with TC2019 > 330.
Rank
(TC2019)		Rank
(C2019)		TitleCountryReference
4 (856)2 (179)Status and distribution of mangrove forests of the world using earth observation satellite dataUSA, Kenya, Australia[2]
5 (821)9 (97)Present state and future of the world’s mangrove forestsAustralia[1]
6 (805)12 (85)Mangrove forests: One of the world’s threatened major tropical environmentsUSA[63]
7 (793)3 (171)Mangroves among the most carbon-rich forests in the tropicsUSA, Indonesia, Finland[6]
8 (643)26 (48)Mangroves enhance the biomass of coral reef fish communities in the CaribbeanUK, Mexico, USA, Canada[64]
9 (634)8 (103)Global carbon sequestration in tidal, saline wetland soilsCanada, USA[15]
16 (428)10 (88)The loss of species: Mangrove extinction risk and geographic areas of global concernUSA, UK, Australia, Philippines, India, Belgium, Japan, Vietnam, Malaysia, Indonesia, China, Singapore[65]
18 (385)62 (29)Spatial variation of heavy metals in surface sediments of Hong Kong mangrove swampsChina[66]
20 (357)39 (40)Factors influencing biodiversity and distributional gradients in mangrovesAustralia[67]
21 (331)104 (22)Why do juvenile fish utilise mangrove habitats?Australia[68]
TC2019: the total number of citations from the Web of Science Core Collection since publication year to the end of 2019; C2019: the number of citations of an article in 2019 only.
Table
Table 7. Top 25 author keywords in publications related to mangroves.
Table 7. Top 25 author keywords in publications related to mangroves.
Author KeywordsTP1990–2019
Rank (%)		1990–1999
Rank (%)		2000–2009
Rank (%)		2010–2019
Rank (%)
mangrove20791 (20)1 (25)1 (22)1 (18)
mangroves13812 (13)2 (21)2 (15)2 (11)
salinity2243 (2.1)3 (3.7)3 (2.4)8 (1.8)
estuary2184 (2.1)28 (1.2)4 (2.3)4 (2.1)
climate change2155 (2.0)63 (0.78)133 (0.41)3 (2.9)
Avicennia marina2076 (2.0)6 (2.4)4 (2.3)9 (1.8)
remote sensing1987 (1.9)33 (1.1)9 (1.7)5 (2.1)
mangrove forest1978 (1.9)33 (1.1)6 (2.1)7 (1.9)
taxonomy1829 (1.7)8 (2.0)34 (1.0)6 (2.0)
sediment17210 (1.6)25 (1.3)13 (1.6)10 (1.7)
conservation15511 (1.5)13 (1.7)11 (1.6)13 (1.4)
Rhizophora mangle15012 (1.4)5 (2.5)8 (1.8)18 (1.1)
biodiversity14813 (1.4)75 (0.67)28 (1.1)12 (1.6)
seagrass14214 (1.4)28 (1.2)15 (1.6)14 (1.3)
heavy metals13115 (1.2)33 (1.1)19 (1.3)16 (1.2)
stable isotopes13115 (1.2)191 (0.34)17 (1.5)15 (1.3)
Avicennia germinans12417 (1.2)17 (1.6)7 (1.9)31 (0.85)
fish11818 (1.1)63 (0.78)23 (1.2)17 (1.1)
blue carbon11719 (1.1)N/AN/A10 (1.7)
brazil10920 (1.0)41 (1.0)10 (1.7)36 (0.8)
sediments10920 (1.0)21 (1.5)23 (1.2)27 (0.93)
diversity10822 (1.0)25 (1.3)43 (0.85)20 (1.1)
Australia10723 (1.0)8 (2.0)15 (1.6)49 (0.68)
Rhizophora10624 (1.0)4 (2.9)21 (1.3)53 (0.67)
nutrients10425 (1.0)7 (2.1)18 (1.4)46 (0.69)
TP: total number of articles; N/A: not available.
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Ho, Y.-S.; Mukul, S.A. Publication Performance and Trends in Mangrove Forests: A Bibliometric Analysis. Sustainability 2021, 13, 12532. https://doi.org/10.3390/su132212532

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Ho Y-S, Mukul SA. Publication Performance and Trends in Mangrove Forests: A Bibliometric Analysis. Sustainability. 2021; 13(22):12532. https://doi.org/10.3390/su132212532

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Ho, Yuh-Shan, and Sharif A. Mukul. 2021. "Publication Performance and Trends in Mangrove Forests: A Bibliometric Analysis" Sustainability 13, no. 22: 12532. https://doi.org/10.3390/su132212532

APA Style

Ho, Y. -S., & Mukul, S. A. (2021). Publication Performance and Trends in Mangrove Forests: A Bibliometric Analysis. Sustainability, 13(22), 12532. https://doi.org/10.3390/su132212532

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