Quantum Information Processing - Journal - Bridge of Knowledge

Search

Quantum Information Processing

ISSN:

1570-0755

eISSN:

1573-1332

Disciplines
(Field of Science):

  • information and communication technology (Engineering and Technology)
  • biomedical engineering (Engineering and Technology)
  • materials engineering (Engineering and Technology)
  • computer and information sciences (Natural sciences)
  • mathematics (Natural sciences)
  • physical sciences (Natural sciences)

Ministry points: Help

Ministry points - current year
Year Points List
Year 2024 100 Ministry scored journals list 2024
Ministry points - previous years
Year Points List
2024 100 Ministry scored journals list 2024
2023 100 Ministry Scored Journals List
2022 100 Ministry Scored Journals List 2019-2022
2021 100 Ministry Scored Journals List 2019-2022
2020 100 Ministry Scored Journals List 2019-2022
2019 100 Ministry Scored Journals List 2019-2022
2018 40 A
2017 40 A
2016 35 A
2015 35 A
2014 40 A
2013 30 A
2012 30 A
2011 30 A
2010 27 A

Model:

Hybrid

Points CiteScore:

Points CiteScore - current year
Year Points
Year 2023 4.1
Points CiteScore - previous years
Year Points
2023 4.1
2022 4
2021 3.6
2020 3.8
2019 3.8
2018 3.5
2017 3.4
2016 3.6
2015 3.2
2014 3
2013 2.6
2012 2.6
2011 2.3

Impact Factor:

Log in to see the Impact Factor.

Filters

total: 3

  • Category
  • Year
  • Options

clear Chosen catalog filters disabled

Catalog Journals

Year 2021
  • Quantum randomness protected against detection loophole attacks
    Publication

    - Quantum Information Processing - Year 2021

    Device and semi-device-independent private quantum randomness generators are crucial for applications requiring private randomness. However, they are vulnerable to detection inefficiency attacks and this limits severely their usage for practical purposes. Here, we present a method for protecting semi-device-independent private quantum randomness generators in prepare-and-measure scenarios against detection inefficiency attacks....

    Full text to download in external service

Year 2020
  • An approach to constructing genuinely entangled subspaces of maximal dimension
    Publication

    Genuinely entangled subspaces (GESs) are the class of completely entangled subspaces that contain only genuinely multiparty entangled states. They constitute a particularly useful notion in the theory of entanglement but also have found an application, for instance, in quantum error correction and cryptography. In a recent study (Demianowicz and Augusiak in Phys Rev A 98:012313, 2018), we have shown how GESs can be efficiently...

    Full text available to download

Year 2010

seen 678 times