Aims and Scope
Aim
Archives of Nuclear Energy Science and Technology aims to provide a premier platform for researchers, practitioners, and policymakers to present their latest findings and methodologies in the field of nuclear energy. Our objectives include:
- Advancing the scientific understanding of nuclear energy systems and their impact on society.
- Promoting interdisciplinary collaboration and research addressing the challenges and opportunities in nuclear energy.
- Encouraging practical applications of research findings to enhance energy security and environmental protection.
- Supporting the development of innovative technologies and policies that promote sustainable nuclear energy.
Scope
The scope of the Archives of Nuclear Energy Science and Technology encompasses a wide range of topics related to nuclear energy, including but not limited to:
Nuclear Reactor Technology: Design, operation, and safety of nuclear reactors.
Radiation Protection: Techniques and regulations for safeguarding public health.
Waste Management: Strategies for the safe disposal and recycling of radioactive materials.
Nuclear Policy: Legal, ethical, and social implications of nuclear energy.
Innovative Research: Emerging technologies, nuclear fusion, and advanced materials.
Types of Contributions We welcome various contributions, including:
- Original research articles presenting new findings.
- Comprehensive reviews summarizing existing knowledge.
- Technical notes detailing preliminary results or innovative methodologies.
- Case studies illustrating practical applications and real-world implications.
Editorial Standards
All submissions to Archives of Nuclear Energy Science and Technology undergo a thorough peer-review process to maintain the highest standards of quality and ethical integrity. We are committed to upholding transparency and reproducibility in all research published in our journal. We invite you to submit your manuscript and contribute to the advancement of knowledge in nuclear energy science and technology. Some of the subject areas that the journal focuses on include: nuclear energy, reactor technology, radiation protection, radioactive waste management, nuclear safety, energy sustainability, nuclear fuel cycles, risk assessment, public health, energy policy, nuclear research, nuclear physics, environmental impact, nuclear engineering, fusion technology, fission technology, and more.
Keywords include:
Nuclear energy |
Lifecycle analysis |
Innovations |
Reactor technology |
Nuclear incident management |
Health physics |
Radiation protection |
Public perception of nuclear energy |
Criticality safety |
Radioactive waste management |
Advanced nuclear reactors |
Nuclear materials |
Nuclear safety |
Small modular reactors |
Radioactive isotopes |
Nuclear policy |
High-temperature gas reactors |
Dosimetry |
Energy sustainability |
Liquid metal fast reactors |
Nuclear power plants |
Nuclear fuel cycles |
Molten salt reactors |
Reactor cooling |
Radiation measurement |
Hybrid energy systems |
Emergency response |
Thermal hydraulics |
Nuclear fusion research |
Nuclear waste disposal |
Reactor design |
Plasma physics |
Spent fuel management |
Nuclear engineering |
Thermonuclear reactions |
Policy analysis |
Environmental impact |
Nuclear thermal propulsion |
Radiation shielding |
Public health |
Isotopic enrichment |
Nuclear regulatory frameworks |
Nuclear physics |
Transmutation of nuclear waste |
Environmental assessments |
Isotopes |
Nuclear supply chain |
Lifecycle analysis |
Fusion technology |
Energy resilience |
Nuclear incident management |
Fission technology |
Radiation biology |
Public perception of nuclear energy |
Nuclear security |
Nuclear forensics |
Advanced nuclear reactors |
Waste disposal |
Environmental remediation |
Small modular reactors |
Energy transition |
Green chemistry in nuclear processes |
High-temperature gas reactors |
Renewable energy integration |
Nuclear data evaluation |
Liquid metal fast reactors |
Risk management |
Reactor simulations |
Waste heat recovery |
Accident analysis |
Radiochemistry |
Radiological assessments |
Decommissioning |
Radiation biology |
Nuclear advocacy |
International regulations |
Neutron activation analysis |
Technology transfer in nuclear research |
Nuclear research |
Nuclear fusion technology |
Nuclear safety culture |
Educational programs |
Photonuclear reactions |
International cooperation in nuclear research |
Energy policy |
Nuclear proliferation |
Global nuclear energy landscape |
Global collaboration |
Fuel cycle analysis |
Nuclear technology commercialization |
Clean energy |
Nuclear security measures |
Advancements in radiation detection |
Energy efficiency |
Climate change mitigation |
Nuclear project management |
Nuclear medicine |
Energy policy development |
Health impacts of radiation exposure |
Radiation therapy |
Nuclear community engagement |
Energy modeling |
Advanced reactors |
Hydrogen production via nuclear energy |
Strategic energy planning |
Reactor physics |
Nuclear education risk communication |
Nuclear technology commercialization |
Computational modeling |
Integrated energy systems |
Advancements in radiation detection |
Neutron transport |
Nuclear fuel fabrication |
Nuclear project management |
Energy systems |
Energy modeling |
Health impacts of radiation exposure |
Radiobiology |
Strategic energy planning |
Molten salt reactors |
Radiation hazards |
Waste heat recovery |
Hybrid energy systems |
Emergency preparedness |
Radiological assessments |
Nuclear fusion research |
Public engagement |
Nuclear advocacy |
Plasma physics |
Stakeholder communication |
Technology transfer in nuclear research |
Thermonuclear reactions |
Sustainability assessments |
Nuclear safety culture |
Nuclear thermal propulsion |
Environmental monitoring |
International cooperation in nuclear research |
Isotopic enrichment |
Nuclear technology |
Global nuclear energy landscape |
Transmutation of nuclear waste |
Innovations |
Nuclear technology commercialization |
Nuclear supply chain |
Health physics |
Advancements in radiation detection |
Energy resilience |
Criticality safety |
Nuclear project management |
Radiation biology |
Nuclear materials |
Health impacts of radiation exposure |
Nuclear forensics |
Radioactive isotopes |
Molten salt reactors |
Environmental remediation |
Dosimetry |
Hybrid energy systems |
Green chemistry in nuclear processes |
Nuclear power plants |
Nuclear fusion research |
Nuclear data evaluation |
Reactor cooling |
Plasma physics |
Reactor simulations |
Emergency response |
Thermonuclear reactions |
Radiochemistry |
Nuclear waste disposal |
Nuclear thermal propulsion |
Radiation biology |
Spent fuel management |
Isotopic enrichment |
Neutron activation analysis |
Policy analysis |
Transmutation of nuclear waste |
Nuclear fusion technology |
Radiation shielding |
Nuclear supply chain |
Photonuclear reactions |
Nuclear regulatory frameworks |
Energy resilience |
Nuclear proliferation |
Environmental assessments |
Radiation biology |
Fuel cycle analysis |
Lifecycle analysis |
Nuclear forensics |
Nuclear security measures |
Nuclear incident management |
Environmental remediation |
Climate change mitigation |
Public perception of nuclear energy |
Green chemistry in nuclear processes |
Energy policy development |
Advanced nuclear reactors |
Nuclear data evaluation |
Nuclear community engagement |
Small modular reactors |
Reactor simulations |
Hydrogen production via nuclear energy |
High-temperature gas reactors |
Radiochemistry |
Nuclear education risk communication |
Liquid metal fast reactors |
Radiation biology |
Integrated energy systems |
Waste heat recovery |
Neutron activation analysis |
Nuclear fuel fabrication |
Radiological assessments |
Nuclear fusion technology |
Advancements in radiation detection |
Nuclear advocacy |
Photonuclear reactions |
Nuclear project management |
Technology transfer in nuclear research |
Nuclear proliferation |
Health impacts of radiation exposure |
Nuclear safety culture |
Fuel cycle analysis |
Energy modeling |
International cooperation in nuclear research |
Nuclear security measures |
Strategic energy planning |
Global nuclear energy landscape |
Climate change mitigation |
Nuclear education risk communication |
Nuclear technology commercialization |
Energy policy development |
Integrated energy systems |
Hydrogen production via nuclear energy |
Nuclear community engagement |
Nuclear fuel fabrication |