CHEMICAL PHYSICS LETTERS - Journal - Bridge of Knowledge

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CHEMICAL PHYSICS LETTERS

ISSN:

0009-2614

eISSN:

1873-4448

Disciplines
(Field of Science):

  • biomedical engineering (Engineering and Technology)
  • chemical engineering (Engineering and Technology)
  • materials engineering (Engineering and Technology)
  • pharmacology and pharmacy (Medical and Health Sciences )
  • astronomy (Natural sciences)
  • chemical sciences (Natural sciences)
  • physical sciences (Natural sciences)

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Ministry points - current year
Year Points List
Year 2024 70 Ministry scored journals list 2024
Ministry points - previous years
Year Points List
2024 70 Ministry scored journals list 2024
2023 70 Ministry Scored Journals List
2022 70 Ministry Scored Journals List 2019-2022
2021 70 Ministry Scored Journals List 2019-2022
2020 70 Ministry Scored Journals List 2019-2022
2019 70 Ministry Scored Journals List 2019-2022
2018 30 A
2017 30 A
2016 25 A
2015 25 A
2014 25 A
2013 30 A
2012 30 A
2011 30 A
2010 32 A

Model:

Hybrid

Points CiteScore:

Points CiteScore - current year
Year Points
Year 2023 5.7
Points CiteScore - previous years
Year Points
2023 5.7
2022 4.7
2021 4.1
2020 3.7
2019 3.5
2018 3.1
2017 3.1
2016 3.3
2015 3.4
2014 3.5
2013 3.7
2012 4.1
2011 4.1

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total: 40

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Catalog Journals

Year 2021
  • Stability and phase transition investigation of olanzapine polymorphs
    Publication
    • J. Tang
    • Y. Han
    • I. Ali
    • H. Luo
    • A. Nowak
    • J. Li

    - CHEMICAL PHYSICS LETTERS - Year 2021

    We use electrical embedded-fragment QM method with both DFT/ωB97XD/6-31G* and MP2/6-31G* to investigate the phase transformations of olanzapine. Gibbs free energy calculations predict that form I is always the most stable structure and form II is the least stable one, while form IV is more stable than form III below about 200 K but less stable above this temperature, implying a polymorphic phase transformation. This may account...

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Year 2019
Year 2018
Year 2017
Year 2016
Year 2015
Year 2014
Year 2011
  • Photophysics and Halide Quenching of Soret-excited ZnTPPS4- in Aqueous Media
    Publication
    • J. Szmytkowski
    • S. M. Brunet
    • U. Tripathy
    • J. A. O'Brien
    • M. F. Paige
    • R. P. Steer

    - CHEMICAL PHYSICS LETTERS - Year 2011

    Steady state S2-S0 and S1-S0 absorption and emission spectra and picosecond S2 decay and S1 fluorescence rise times have been measured for the model porphyrin ZnTPPS4− in water and in aqueous iodide solutions of constant ionic strength. The dynamics of S1 quenching by iodide are well-modeled by a Stern-Volmer mechanism yielding kQ = 1.75 × 109 M−1 s−1. The S2 state is quenched on a ps time scale by a static electron-transfer mechanism...

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Year 2010
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