Osvaldo Civitarese | Weak interactions | Editorial Board Member

Published on by Physicist Particle

Editorial Board Member

Osvaldo Civitarese
Particle Physics and Cosmology Researcher
Affiliation Universidad Nacional de La Plata (UNLP)
Country Argentina
Scopus ID 7005690970
Documents 352
Citations 5,301
h-index 37
Subject Area Particle physics and cosmology
Event Global Particle Physics Excellence Awards
ORCID 0000-0001-5447-850X

Osvaldo Civitarese is a physicist affiliated with the Universidad Nacional de La Plata (UNLP), Argentina, whose scholarly work has contributed extensively to the fields of particle physics, nuclear theory, neutrino physics, cosmology, and quantum statistical mechanics. His publication record includes a broad range of peer-reviewed journal articles, conference papers, and theoretical investigations involving neutrino interactions, dark matter models, axion-neutrino couplings, double-beta decay, and quantum many-body systems.[1] His academic profile reflects sustained international collaboration and a consistent research presence within high-impact physics journals and interdisciplinary cosmological studies.[2]

Abstract

The academic work of Osvaldo Civitarese spans several interconnected domains within theoretical and particle physics, including neutrino oscillations, dark matter phenomenology, nuclear structure calculations, axion-neutrino interactions, and quantum statistical mechanics. His contributions have supported theoretical investigations into astrophysical neutrino propagation, quantum unstable states, and particle interaction modeling in cosmological environments.[2] Through an extensive body of peer-reviewed publications and collaborations, he has contributed to the broader understanding of particle interactions and cosmological processes relevant to modern theoretical physics.[3]

Keywords

Particle physics, cosmology, neutrino physics, dark matter, axion interactions, double-beta decay, quantum statistical mechanics, nuclear structure theory, astrophysical neutrinos, theoretical physics.

Introduction

Theoretical particle physics and cosmology continue to play a critical role in understanding the fundamental structure of matter, energy, and the evolution of the universe. Researchers working in these disciplines contribute to the development of models that explain neutrino behavior, dark matter interactions, quantum field dynamics, and astrophysical processes. Osvaldo Civitarese has participated in these scientific developments through theoretical studies focused on neutrino mass mechanisms, nuclear matrix elements, cosmological particle interactions, and quantum systems.[2]

His academic profile demonstrates long-term involvement in nuclear and particle theory, supported by collaborations across international research groups and publications in journals such as Physical Review C, Physical Review D, Physics Letters B, and International Journal of Modern Physics E.[4]

Research Profile

According to Scopus author records, Osvaldo Civitarese has authored or co-authored 352 scholarly documents and accumulated more than 5,301 citations, with an h-index of 37.[1] His affiliation with Universidad Nacional de La Plata reflects continued engagement in advanced theoretical physics research and academic mentoring.[2]

His ORCID profile additionally documents academic appointments, educational background, and international research activities, including postdoctoral training at the University of Copenhagen and support from the Alexander von Humboldt Foundation.[2]

  • Specialization in neutrino physics and cosmological particle interactions.
  • Research contributions involving dark matter and axion-neutrino coupling models.
  • Extensive publication activity in nuclear and particle physics journals.
  • Participation in theoretical modeling of astrophysical and quantum systems.

Research Contributions

Civitarese has contributed to theoretical studies concerning neutrinoless double-beta decay and the effective axial-vector current coupling relevant to nuclear transition calculations.[3] These investigations are relevant for understanding neutrino mass generation and weak interaction processes in nuclear systems.

His work on axion-neutrino couplings and dark matter phenomenology has explored the implications of Peccei–Quinn symmetry breaking, axion mass hierarchy, and neutrino interactions within cosmological environments.[4] These studies connect theoretical particle models with observable cosmological phenomena and astrophysical constraints.

Additional research has focused on quantum unstable states, Gamow states, and statistical mechanics, including investigations into entropy, quantum resonance structures, and non-perturbative quantum chromodynamics.[5]

Publications

Selected publications associated with Osvaldo Civitarese include contributions to nuclear theory, cosmology, neutrino physics, and statistical mechanics.[3]

Research Impact

The research output associated with Osvaldo Civitarese demonstrates sustained influence within theoretical and particle physics literature. His citation metrics and publication history indicate scholarly engagement across nuclear theory, cosmology, astrophysical neutrino studies, and quantum mechanics.[1]

Several of his investigations contribute to contemporary discussions involving neutrino mass hierarchy, dark matter interactions, and quantum statistical systems, which remain important areas of inquiry in modern particle physics and cosmology.[4]

Award Suitability

Osvaldo Civitarese’s academic achievements, publication record, citation impact, and sustained theoretical contributions support recognition within international scientific forums related to particle physics and cosmology. His multidisciplinary research spanning neutrino theory, dark matter physics, and nuclear structure calculations aligns with the scholarly objectives of the Global Particle Physics Excellence Awards.[1]

His role as an emeritus professor and active contributor to ongoing theoretical research further demonstrates long-standing engagement with scientific advancement and academic collaboration.[2]

Conclusion

The academic profile of Osvaldo Civitarese reflects a substantial contribution to theoretical particle physics, cosmology, and nuclear physics research. Through extensive scholarly publications, international collaborations, and investigations into neutrino phenomena, dark matter interactions, and quantum systems, he has contributed to the development of modern theoretical frameworks within high-energy and astrophysical physics.[3]

References

  1. Elsevier. (2026). Scopus author details: Osvaldo Civitarese, Author ID 7005690970. Scopus Preview.
    https://www.scopus.com/authid/detail.uri?authorId=7005690970
  2. ORCID. (2026). Osvaldo Civitarese ORCID profile.
    https://orcid.org/0000-0001-5447-850X
  3. Civitarese, O., Fassari, S., Gadella, M., & Rinaldi, F. (2025). The Birman–Schwinger operator for the Cornell Hamiltonian. European Physical Journal Plus.
    https://doi.org/10.1140/epjp/s13360-025-07192-1
  4. Civitarese, O. (2024). On the Breaking of the U(1) Peccei–Quinn Symmetry and Its Implications for Neutrino and Dark Matter Physics. Symmetry.
    https://doi.org/10.3390/sym16030364
  5. Civitarese, O., & Gadella, M. (2024). On the Concept of Quantum-Unstable States in Statistical Mechanics: The Case of the Entropy. SSRN.
    https://doi.org/10.2139/ssrn.4712942

Riasat Ali | Particle physics and cosmology | Editorial Board Member | 3098

Published on by Physicist Particle

Editorial Board Member

Riasat Ali
Riasat Ali
Affiliation Shanghai University
Country China
Scopus ID 57212863194
Documents 76
Citations 1,159
h-index 20
Subject Area Particle Physics and Cosmology
Event Global Particle Physics Excellence Awards
ORCID Connected via Scopus

Riasat Ali is a researcher affiliated with Shanghai University, China, whose academic work focuses on particle physics, cosmology, black hole physics, gravitation, and related theoretical investigations. His research profile demonstrates continuous scholarly engagement in contemporary astrophysical and gravitational studies, particularly in modified gravity models, plasma effects on black hole shadows, and quantum gravity-inspired thermodynamics.[1]

Abstract

This article presents an overview of the academic profile and scholarly contributions of Riasat Ali in the fields of particle physics and cosmology. His research portfolio includes investigations into black hole thermodynamics, plasma-induced gravitational lensing, Hawking radiation, and modified gravity theories. Through publications in recognized international journals, his work contributes to ongoing discussions in theoretical astrophysics and gravitational physics.[1][2]

Keywords

Particle physics, cosmology, black hole physics, Horndeski gravity, Hawking radiation, plasma physics, gravitational lensing, modified gravity, astrophysics, quantum gravity.

Introduction

Theoretical particle physics and cosmology continue to provide important frameworks for understanding gravitational phenomena, spacetime geometry, and high-energy astrophysical systems. Researchers working in these areas frequently examine black hole behavior, quantum corrections, and observational signatures associated with relativistic environments. Riasat Ali has contributed to these themes through studies involving black hole shadows, photon deflection, and thermodynamic properties within alternative gravity frameworks.[2]

Research Profile

According to Scopus author records, Riasat Ali has authored or co-authored 76 indexed documents and accumulated more than 1,159 citations with an h-index of 20. His publications primarily focus on gravitational physics, black hole thermodynamics, plasma effects in astrophysical systems, and modified theories of gravity.[1]

His recent works examine topics such as charged hairy black holes in Horndeski gravity, photon deflection in dispersive media, and generalized uncertainty principle corrections in black hole systems. These investigations contribute to the broader understanding of relativistic astrophysical environments and quantum-inspired gravitational models.[2]

Research Contributions

  • Investigated unstable equilibrium and chaos-bound violations in charged hairy black holes within Horndeski gravity frameworks.
  • Studied photon deflection and black hole shadow formation under the influence of plasma and dispersive media.
  • Explored Hawking temperature corrections and thermodynamic properties associated with generalized uncertainty principles.
  • Published research associated with modified gravity theories including Rastall gravity and f(Q,BQ) gravity models.

Publications

  1. “Unstable equilibrium and chaos-bound violation for a charged hairy black hole in Horndeski gravity,” New Astronomy, 2026.
  2. “Deflection of photon and shadow cast for black hole spacetime under the impact of a dispersive medium,” Indian Journal of Physics, 2026.
  3. “Greybody Factor and Hawking Temperature of ModMax-AdS Black Holes Surrounded by Perfect Fluid Dark Matter,” Fortschritte Der Physik, 2025.
  4. “Exploring plasma and dark matter on photon deflection by Reissner–Nordström black hole with scalar hair and its shadow,” Annals of Physics, 2025.

Research Impact

The research contributions of Riasat Ali demonstrate interdisciplinary engagement between cosmology, astrophysics, and gravitational theory. His publication metrics and citation record indicate continued academic visibility within theoretical physics communities. The integration of plasma physics, dark matter models, and quantum corrections into black hole studies reflects current directions in modern gravitational research.[1]

Award Suitability

Riasat Ali’s research profile aligns with the objectives of the Global Particle Physics Excellence Awards, particularly in the recognition of emerging contributions to theoretical particle physics and cosmology. His sustained publication activity, citation impact, and involvement in advanced gravitational studies support his suitability for editorial and scholarly recognition within the international academic community.

Conclusion

Riasat Ali has established a notable academic presence in the domains of particle physics and cosmology through research on black hole dynamics, modified gravity, and relativistic astrophysics. His scholarly activities, publication output, and citation performance indicate active participation in contemporary theoretical physics research and continued contribution to advancing cosmological understanding.

References

  1. Elsevier. (2026). Scopus author details: Riasat Ali, Author ID 57212863194. Scopus.
    http://scopus.com/authid/detail.uri?authorId=57212863194
  2. Ali, R. H. (2026). Unstable equilibrium and chaos-bound violation for a charged hairy black hole in Horndeski gravity. New Astronomy.
    10.1016/j.newast.2026.102564
  3. Ali, R. H. (2025). Exploring plasma and dark matter on photon deflection by Reissner–Nordström black hole with scalar hair and its shadow. Annals of Physics.
    https://doi.org/10.1016/j.aop.2025.170201
  4. Google Scholar. (2026). Riasat Ali citation profile.
    https://scholar.google.com/citations?user=Stp2lpMAAAAJ&hl=en

Gregory Vereshchagin | Cosmology and Physics | Research Excellence Award

Published on by Physicist Particle

Research Excellence Award

Gregory Vereshchagin — ICRANet
Gregory Vereshchagin
Affiliation ICRANet
Country Italy
Scopus ID 8686090800
Documents 104
Citations 1,628
h-index 19
Subject Area Cosmology and Physics
Event Global Particle Physics Excellence Awards

The Research Excellence Award recognizes the sustained scholarly contributions of Gregory Vereshchagin in the fields of cosmology, gravitation, and theoretical physics. Affiliated with ICRANet, Vereshchagin has contributed to the advancement of contemporary astrophysical and cosmological research through publications, collaborative investigations, and theoretical modeling relevant to particle physics and early-universe studies.[1] His work has addressed important themes involving relativistic cosmology, inflationary models, dark energy, and quantum aspects of the universe.[2]

Abstract

Gregory Vereshchagin has developed a research portfolio centered on cosmological physics, gravitational theory, and particle cosmology. His scholarly work explores theoretical frameworks associated with the evolution of the universe, relativistic astrophysics, and inflationary cosmology. The academic record associated with his Scopus profile indicates broad engagement with interdisciplinary studies connecting gravitation, cosmology, and high-energy theoretical physics.[1] The Research Excellence Award acknowledges these scientific contributions and their relevance to the ongoing development of cosmological research methodologies and theoretical interpretation.[3]

Keywords

Cosmology, Particle Physics, Relativistic Astrophysics, Inflationary Models, Gravitation Theory, Early Universe Physics, Quantum Cosmology, High-Energy Physics, Dark Energy, Theoretical Physics

Introduction

The study of cosmology and particle physics has increasingly relied on interdisciplinary theoretical approaches capable of integrating astrophysical observations with advanced mathematical frameworks. Researchers contributing to this field often address questions concerning the origin, structure, and evolution of the universe. Gregory Vereshchagin has participated in this scientific discourse through investigations connected to cosmological dynamics and relativistic models.[2]

His research activity has been associated with ICRANet, an institution internationally recognized for work in relativistic astrophysics and cosmology. Through collaborative publications and theoretical analyses, Vereshchagin has contributed to scientific discussions regarding inflationary cosmology, quantum gravity considerations, and cosmological perturbation theory.[4]

Research Profile

The Scopus profile associated with Gregory Vereshchagin identifies a sustained publication record comprising more than one hundred indexed documents and a citation count exceeding one thousand references from the scientific community.[1] His h-index reflects continued scholarly engagement and measurable research visibility within the domains of cosmology and theoretical physics.

Research themes appearing across his publication history include:

  • Inflationary and cyclic cosmological models
  • Relativistic astrophysics and gravitation
  • Quantum cosmological frameworks
  • Dark energy and vacuum dynamics
  • Mathematical approaches to particle cosmology

Research Contributions

Gregory Vereshchagin has contributed to theoretical analyses investigating the relationship between cosmological evolution and particle interactions. Several studies have examined inflationary mechanisms capable of explaining large-scale structure formation and cosmic microwave background phenomena.[5]

Additional work has focused on mathematical models describing the dynamics of the early universe under relativistic conditions. Such investigations are significant within particle physics because they support theoretical interpretations related to matter distribution, cosmological singularities, and quantum gravitational effects.

His publications have also addressed interdisciplinary themes involving astrophysics, gravitation theory, and cosmological perturbations. These contributions support broader efforts to refine predictive cosmological models and improve theoretical consistency within modern astrophysics.

Publications

Selected publication themes and representative scholarly outputs include:

  • Research on inflationary cosmology and early-universe models associated with particle physics.[5]
  • Studies addressing relativistic cosmology and quantum gravitational frameworks.
  • Collaborative publications involving cosmological perturbations and theoretical astrophysics.
  • Scientific discussions concerning dark energy and cosmological expansion theories.

Research Impact

The citation record connected with Gregory Vereshchagin’s publications demonstrates continued engagement from researchers working in cosmology, astrophysics, and particle physics. His contributions are referenced in studies related to inflationary cosmology, relativistic dynamics, and quantum gravity theories.[1]

The international visibility of his work is further reflected through collaborative institutional associations and indexing within global scientific databases. Such metrics indicate sustained scholarly relevance and contribution to theoretical scientific inquiry.[3]

Award Suitability

The Global Particle Physics Excellence Awards recognize researchers whose scientific activities contribute meaningfully to the advancement of theoretical and experimental particle physics. Gregory Vereshchagin’s academic record demonstrates alignment with these objectives through sustained research productivity, citation impact, and theoretical contributions to cosmological physics.

His work within cosmology and high-energy theoretical physics supports ongoing efforts to understand the physical principles governing the universe. The breadth of his scholarly engagement and the interdisciplinary relevance of his publications support his recognition within the context of international scientific awards.[2]

Conclusion

Gregory Vereshchagin has established a notable academic presence within the fields of cosmology and theoretical physics through publications, collaborative research, and contributions to cosmological theory. His affiliation with ICRANet and his documented scientific output reflect sustained engagement with important questions concerning the origin and evolution of the universe.[1] The Research Excellence Award acknowledges these contributions and their continuing relevance to global scientific research in particle physics and cosmology.

References

  1. Elsevier. (n.d.). Scopus author details: Gregory Vereshchagin, Author ID 8686090800. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=8686090800
  2. ORCID. (n.d.). ORCID profile of Gregory Vereshchagin.
    https://orcid.org/0000-0002-1623-3576
  3. Vereshchagin, G. (2003). Pair luminosity and cooling of newborn strange star: Unpaired quarks.
    https://www.researchgate.net/publication/399514216_Pair_luminosity_and_cooling_of_newborn_strange_star_Unpaired_quarks
  4. Vereshchagin, G., et al. (2002). Role of the neutral X-fermion in describing the dark matter of the universe.
    https://link.springer.com/article/10.1140/epjc/s10052-025-14404-6
  5. Physicist Particle. (n.d.). Global Particle Physics Excellence Awards.

    Global Particle Physics Excellence Awards