ISSN:
eISSN:
Disciplines
(Field of Science):
- architecture and urban planning (Engineering and Technology)
- automation, electronics, electrical engineering and space technologies (Engineering and Technology)
- biomedical engineering (Engineering and Technology)
- materials engineering (Engineering and Technology)
- mechanical engineering (Engineering and Technology)
- medical biology (Medical and Health Sciences )
- international relations (Social studies)
- biotechnology (Natural sciences)
- chemical sciences (Natural sciences)
(Field of Science)
Ministry points: Help
Year | Points | List |
---|---|---|
Year 2024 | 200 | Ministry scored journals list 2024 |
Year | Points | List |
---|---|---|
2024 | 200 | Ministry scored journals list 2024 |
2023 | 200 | Ministry Scored Journals List |
2022 | 200 | Ministry Scored Journals List 2019-2022 |
2021 | 200 | Ministry Scored Journals List 2019-2022 |
2020 | 200 | Ministry Scored Journals List 2019-2022 |
2019 | 200 | Ministry Scored Journals List 2019-2022 |
2018 | 45 | A |
2017 | 45 | A |
2016 | 45 | A |
2015 | 45 | A |
2014 | 45 | A |
2013 | 45 | A |
Model:
Points CiteScore:
Year | Points |
---|---|
Year 2023 | 41.9 |
Year | Points |
---|---|
2023 | 41.9 |
2022 | 42.6 |
2021 | 46.7 |
2020 | 41.1 |
2019 | 35.4 |
2018 | 28.4 |
2017 | 26.1 |
2016 | 22 |
2015 | 21.2 |
2014 | 20.4 |
2013 | 14.2 |
2012 | 6.8 |
2011 | 2.3 |
Impact Factor:
Sherpa Romeo:
Papers published in journal
Filters
total: 2
Catalog Journals
Year 2024
-
Sub‐Nanometer‐Scale Cu9S5 Enables Efficiently Electrochemical Nitrate Reduction to Ammonia
PublicationThe sub-nanometer is a key feature size in materials science. Unlike single-atom and nanomaterials, size effects and inter-component cooperative actions in sub-nanomaterials will effective on its performance is more significant. Here, 0.95 nm ordered arrangement Cu9S5 sub-nanowires (Cu9S5 SNWs) are synthesized through the co-assembly effect of inorganic nuclei (Cu9S5) and clusters (phosphotungstic acid-PTA), achieving a significant...
Year 2015
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SEI Growth and Depth Profiling on ZFO Electrodes by Soft X-Ray Absorption Spectroscopy
PublicationZnFe2O4 (ZFO) Li-ion batteries (LIBs) represent a reliable, affordable, and safe energy storage technology for use in portable application. However, current LIB active materials (graphite, lithium/transition metal spinel or layered oxides, olivine structures) can store only limited energy since they rely on insertion storage based on solid-state host-guest interactions. Moreover, performances and durability of the cells are strongly...
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