Biomaterials Translational ›› 2023, Vol. 4 ›› Issue (3): 131-141.doi: 10.12336/biomatertransl.2023.03.002
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Tai–Long Shi1,2,3, Yi–Fan Zhang1,2,3, Meng–Xuan Yao1,2,3, Chao Li1,2,3, Hai–Cheng Wang1,2,3, Chuan Ren1,2,3, Jun–Sheng Bai1,2,3, Xu Cui4, Wei Chen1,2,3,*()
Received:
2023-08-16
Revised:
2023-09-09
Accepted:
2023-09-12
Online:
2023-09-28
Published:
2023-09-28
Contact:
*Wei Chen,
Shi, T. L; Zhang, Y, F.; Yao, M. X.; Li, C.; Wang, H. C.; Ren, C.; Bai, J. S.; Cui, X.; Chen, W. Global trends and hot topics in clinical applications of perovskite materials: a bibliometric analysis. Biomater Transl. 2023, 4(3), 131-141.
Description | Results |
---|---|
Main information about data | |
Timespan | 1983–2022 |
Sources | 447 |
Documents | 1708 |
Annual growth rate (%) | 4.11 |
Document average age (year) | 5.66 |
Average citations per document | 39.61 |
References | 61233 |
Document contents | |
Keywords plus (ID) | 3480 |
Author’s keywords (DE) | 3714 |
Authors | |
Total number of authors | 7193 |
Authors of single–authored documents | 15 |
Authors collaboration | |
Single–authored documents | 17 |
Co–authors per document | 6.87 |
International co–authorships (%) | 37.82 |
Document types | |
Research article | 1584 |
Review | 124 |
Table 1. General information of all publications on perovskite materials in the Web of Science database
Description | Results |
---|---|
Main information about data | |
Timespan | 1983–2022 |
Sources | 447 |
Documents | 1708 |
Annual growth rate (%) | 4.11 |
Document average age (year) | 5.66 |
Average citations per document | 39.61 |
References | 61233 |
Document contents | |
Keywords plus (ID) | 3480 |
Author’s keywords (DE) | 3714 |
Authors | |
Total number of authors | 7193 |
Authors of single–authored documents | 15 |
Authors collaboration | |
Single–authored documents | 17 |
Co–authors per document | 6.87 |
International co–authorships (%) | 37.82 |
Document types | |
Research article | 1584 |
Review | 124 |
Figure 4. Keyword co–occurrence analysis of all publications on perovskite materials in the Web of Science database. (A) The number of articles published, the number of articles applied, and the average number of articles applied in VOS viewer. (B) Use VOS viewer to visualize the institutional co–occurrence network. Large nodes indicate that the occurrence rate of keywords is higher. The same colour indicates a close relationship. (C) Annual number of publications by the top five most productive institutions. In each group, the larger the node, the higher the frequency of the keyword; the denser the line, the closer their relationship. “Conversion” and “highly performance” not only have a high frequency of appearance, but also have a close relationship.
Rank | Journal | Publicationsa | Total citations | H index | Impact factor (2021) | Co–cited journal | Co–citations | Impact factor (2021) of co–cited journal |
---|---|---|---|---|---|---|---|---|
1 | Solid State Ionics | 40 | 4396 | 25 | 3.7 | Advanced Materials | 777 | 32.09 |
2 | Advanced Materials | 29 | 2440 | 21 | 32.09 | Journal of the American Chemical Society | 740 | 16.38 |
3 | ACS Applied Materials & Interfaces | 46 | 1051 | 18 | 10.38 | Science | 736 | 63.71 |
4 | Journal of Materials Chemistry A | 24 | 1073 | 18 | 19.92 | Nature | 717 | 69.5 |
5 | Advanced Functional Materials | 30 | 1118 | 15 | 3.75 | Chemistry of Materials | 607 | 10.51 |
6 | Chemistry of Materials | 23 | 2263 | 15 | 10.51 | Nature Communications | 601 | 17.69 |
7 | Chinese Chemical Letters | 39 | 715 | 15 | 8.46 | ACS Applied Materials & Interfaces | 582 | 10.38 |
8 | Journal of Materials Chemistry C | 28 | 473 | 13 | 8.07 | Advanced Functional Materials | 574 | 19.92 |
9 | Journal of Alloys and Compounds | 24 | 595 | 12 | 6.37 | Nano Letters | 535 | 12.26 |
Table 2. The top nine most prolific journals and co–cited journals with the most publications related to novel clinical applications of perovskite materials
Rank | Journal | Publicationsa | Total citations | H index | Impact factor (2021) | Co–cited journal | Co–citations | Impact factor (2021) of co–cited journal |
---|---|---|---|---|---|---|---|---|
1 | Solid State Ionics | 40 | 4396 | 25 | 3.7 | Advanced Materials | 777 | 32.09 |
2 | Advanced Materials | 29 | 2440 | 21 | 32.09 | Journal of the American Chemical Society | 740 | 16.38 |
3 | ACS Applied Materials & Interfaces | 46 | 1051 | 18 | 10.38 | Science | 736 | 63.71 |
4 | Journal of Materials Chemistry A | 24 | 1073 | 18 | 19.92 | Nature | 717 | 69.5 |
5 | Advanced Functional Materials | 30 | 1118 | 15 | 3.75 | Chemistry of Materials | 607 | 10.51 |
6 | Chemistry of Materials | 23 | 2263 | 15 | 10.51 | Nature Communications | 601 | 17.69 |
7 | Chinese Chemical Letters | 39 | 715 | 15 | 8.46 | ACS Applied Materials & Interfaces | 582 | 10.38 |
8 | Journal of Materials Chemistry C | 28 | 473 | 13 | 8.07 | Advanced Functional Materials | 574 | 19.92 |
9 | Journal of Alloys and Compounds | 24 | 595 | 12 | 6.37 | Nano Letters | 535 | 12.26 |
Rank | First Author | Title | Local citations | Journal | Publication year |
---|---|---|---|---|---|
1 | Yong Churl Kim | Printable organometallic perovskite enables large–area, low–dose X–ray imaging | 73 | Nature | 2017 |
2 | Qiushui Chen | All–inorganic perovskite nanocrystal scintillators | 70 | Nature | 2018 |
3 | Weicheng Pan | Cs2AgBiBr6 single–crystal X–ray detectors with a low detection limit | 60 | Nature | 2017 |
4 | Renzhong Zhuang | Highly sensitive X–ray detector made of layered perovskite–like (NH4)3Bi2I9 single crystal with anisotropic response | 35 | Nature | 2019 |
5 | Ajay Kumar Jena | Halide perovskite photovoltaics: background, status, and future prospects | 31 | Chemical Reviews | 2019 |
6 | Yuhai Zhang | Metal halide perovskite nanosheet for Xray high–resolution scintillation imaging screens | 29 | ACS Nano | 2019 |
7 | Yunxia Zhang | Nucleation–controlled growth of superior lead–free perovskite Cs3Bi2I9 single–crystals for high–performance X–ray detection | 29 | Nature Communications | 2020 |
8 | Sergii Yakunin | Detection of gamma photons using solution–grown single crystals of hybrid lead halide perovskites | 27 | Nature | 2016 |
9 | M D Birowosuto | X–ray scintillation in lead halide perovskite crystals | 24 | Scientific Reports | 2016 |
10 | Weicheng Pan | Hot–pressed CsPbBr3 quasi–monocrystalline film for sensitive direct X–ray detection | 23 | Advanced Materials | 2019 |
Table 3. The top ten most cited publications with the most publications related to novel clinical applications of perovskite materials
Rank | First Author | Title | Local citations | Journal | Publication year |
---|---|---|---|---|---|
1 | Yong Churl Kim | Printable organometallic perovskite enables large–area, low–dose X–ray imaging | 73 | Nature | 2017 |
2 | Qiushui Chen | All–inorganic perovskite nanocrystal scintillators | 70 | Nature | 2018 |
3 | Weicheng Pan | Cs2AgBiBr6 single–crystal X–ray detectors with a low detection limit | 60 | Nature | 2017 |
4 | Renzhong Zhuang | Highly sensitive X–ray detector made of layered perovskite–like (NH4)3Bi2I9 single crystal with anisotropic response | 35 | Nature | 2019 |
5 | Ajay Kumar Jena | Halide perovskite photovoltaics: background, status, and future prospects | 31 | Chemical Reviews | 2019 |
6 | Yuhai Zhang | Metal halide perovskite nanosheet for Xray high–resolution scintillation imaging screens | 29 | ACS Nano | 2019 |
7 | Yunxia Zhang | Nucleation–controlled growth of superior lead–free perovskite Cs3Bi2I9 single–crystals for high–performance X–ray detection | 29 | Nature Communications | 2020 |
8 | Sergii Yakunin | Detection of gamma photons using solution–grown single crystals of hybrid lead halide perovskites | 27 | Nature | 2016 |
9 | M D Birowosuto | X–ray scintillation in lead halide perovskite crystals | 24 | Scientific Reports | 2016 |
10 | Weicheng Pan | Hot–pressed CsPbBr3 quasi–monocrystalline film for sensitive direct X–ray detection | 23 | Advanced Materials | 2019 |
Figure 5. Keyword co–occurrence analysis of all publications on perovskite materials in the Web of Science database. (A) Use VOS viewer to visualize author keyword co–occurrence network. (B) Keywords that appear the most. The larger the font, the higher the frequency of keywords. (C) The initial keyword with the most significant citation burst signifies the prominent topics during different time periods. The red bars indicate the duration of the burst period, highlighting the intensification of interest. The strength of the burst indicates the importance of the topic to the field of study.
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