Particle accelerator sweden

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Particle Accelerator Research and Development in Sweden

MAX IV Laboratory: Precision Realignment and Advanced X-ray Production

The MAX IV Laboratory, located in Sweden, is renowned for producing the world's most brilliant X-rays, which are pivotal for various research applications. This facility includes two storage rings and a 300-meter linear accelerator, which require meticulous alignment of hundreds of components. The alignment process is critical to ensure the precision and functionality of the accelerator. Recently, a comprehensive realignment of the linear accelerator was undertaken due to beam-based measurements indicating alignment deflections since its initial setup in 2015. This realignment process, which spanned over two years, involved surveying, outlier analysis, fiducialization, and optimization of reference networks to maintain consistency with the already operational storage rings and beamlines .

Accelerator-Driven Systems: Research and Development in Sweden

Sweden has shown significant interest in accelerator-driven transmutation systems, particularly for nuclear waste management. This interest was sparked by the Specialist Meeting on Accelerator-Driven Transmutation Technology for Radwaste and other Applications held in Saltsjöbaden, Sweden, in 1991. Since then, several research centers in Sweden have initiated studies on these systems, supported by governmental agencies and the nuclear power industry. The research focuses on the safety aspects and potential applications of accelerator-driven systems, aiming to develop reliable and intense neutron sources for various uses .

Innovative Ecosystem for Accelerator Science and Technology

The development of particle accelerators in Sweden is supported by a robust ecosystem that includes research infrastructures, industries, and educational institutions. This ecosystem fosters collaboration and innovation, essential for advancing accelerator science and technology. The European Spallation Source (ESS) in Lund, Sweden, exemplifies this ecosystem, promoting technology and knowledge transfer through scientific communication, education, and collaboration. The Lund Institute for Advanced Neutron and X-ray Science (LINXS) plays a crucial role in training human resources and facilitating the use of scientific infrastructures for both academic and industrial purposes .

Conclusion

Sweden's contributions to particle accelerator research and development are significant, with facilities like the MAX IV Laboratory and initiatives in accelerator-driven systems leading the way. The country's innovative ecosystem, exemplified by the ESS and LINXS, supports continuous advancements in accelerator technology, ensuring that Sweden remains at the forefront of this critical scientific field.

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Most relevant research papers on this topic

Data analysis, spatial metrology network, and precision realignment of the entire MAX IV linear accelerator

MAX IV linear accelerator underwent a successful precision realignment process over 2 years, maintaining consistency with existing storage rings and beamlines.

2021·

19citations

·B. Afzali-Far et al.

Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment·

DOI

Accelerator‐driven nuclear synergetic systems—An overview of the research activities in Sweden

Swedish research on accelerator-driven nuclear synergetic systems shows promising potential for transforming spent fuel into useful products, with potential for future collaboration with the nuclear power industry and utilities.

2008·

0citations

·H. Condé et al.

DOI

An Innovative Eco-System for Accelerator Science and Technology

An innovative ecosystem of research infrastructure, academia, and industry can maximize the potential of particle accelerators, contributing to economic and social transformation.

2021·

0citations

·C. Darve et al.

DOI

On-chip integrated laser-driven particle accelerator

Miniaturized dielectric laser accelerators can accelerate 80-keV electrons along 30 micrometers, offering a compact and cost-effective solution for particle physics applications.

2019·

177citations

·N. Sapra et al.

Science·

DOI

On the use of Radioactive Substances in Sweden, with Special Reference to Irradiation Risks and Protection Measures

Sweden's use of radioactive substances, particularly radium and radon, is primarily from the viewpoint of radiation protection, with some useful devices and protection measures for particle accelerators.

1950·

1citation

·S. Benner

Acta Radiologica·

DOI

Stable and Scalable Multistage Terahertz-Driven Particle Accelerator.

A miniaccelerator powered by terahertz pulses enables stable and scalable beam acceleration in a multistage miniaccelerator, paving the way for functioning terahertz-driven high-energy accelerators.

2021·

42citations

·Heng Tang et al.

Physical review letters·

DOI

Miniaturizing particle accelerators

Miniaturized dielectric laser accelerators could open up particle physics to various scientific disciplines by providing additional kicks to 80-keV electrons along just 30 micrometers of a specially designed channel.

2020·

0citations

·I. Osborne

Science·

DOI

Plasma based charged-particle accelerators

Laser plasma accelerators using intense lasers and electron beams show promise for ultra-high acceleration gradients, potentially producing GeV particles in the near future.

Literature Review

2003·

211citations

·R. Bingham et al.

Plasma Physics and Controlled Fusion·

DOI

A laser–plasma accelerator producing monoenergetic electron beams

Laser-plasma accelerators can produce high-quality electron beams with reduced randomization, potentially revolutionizing compact particle accelerators for applications in medicine and biology.

2004·

1935citations

·J. Faure et al.

Nature·

DOI

European Strategy for Particle Physics -- Accelerator R&D Roadmap

European accelerator R&D roadmap aims to improve performance and cost-efficiency of magnet and radio-frequency systems, investigate laser/plasma acceleration techniques, and develop new concepts for muon beams and muon colliders.

2022·

70citations

·C. Adolphsen et al.

DOI

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