Advances in Nb<sub>3</sub>Sn superconducting radiofrequency cavities towards first practical accelerator applications

Posen, S.; Lee, J.; Seidman, David N.; Romanenko, Alexander; Tennis, B.; Melnychuk, Oleksandr; Sergatskov, Dmitri

doi:10.1088/1361-6668/abc7f7

Cited by 63 publications

(56 citation statements)

References 42 publications

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“…Extrapolation from high power pulsed RF experiments is in agreement with this prediction [36]. In CW regime, Nb 3 Sn deposited on bulk niobium cavities show promising results [37], reaching high Q ∼ 10 10 even at temperatures ∼ 4 K. So far, R&D cavities demonstrated accelerating gradients up to 24 MV/m in single-cell cavities and 15 MV/m in 9-cell TESLA-shape cavities [38]. Such gradients might already be useful for small-scale accelerators.…”

Section: Nb 3 Sn As Practical Nb Materialssupporting

confidence: 73%

Key directions for research and development of superconducting radio frequency cavities

Belomestnykh,

Posen,

Bafia

et al. 2022

Preprint

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Radio frequency superconductivity is a cornerstone technology for many future HEP particle accelerators and experiments from colliders to proton drivers for neutrino facilities to searches for dark matter. While the performance of superconducting RF (SRF) cavities has improved significantly over the last decades, and the SRF technology has enabled new applications, the proposed HEP facilities and experiments pose new challenges. To address these challenges, the field continues to generate new ideas and there seems to be a vast room for improvements. In this paper we discuss the key research directions that are aligned with and address the future HEP needs.

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Section: Nb 3 Sn As Practical Nb Materialssupporting

confidence: 73%

Key directions for research and development of superconducting radio frequency cavities

Belomestnykh,

Posen,

Bafia

et al. 2022

Preprint

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“…Indeed, this sort of strategy is being pursued by ADMX for their small "sidecar" cavities [122]. A similar approach could be implemented in multi-cell cavities of the type typically used for RF acceleration [124].…”

Section: A Sensitivity Estimatementioning

confidence: 99%

Detecting High-Frequency Gravitational Waves with Microwave Cavities

Berlin,

Blas,

D'Agnolo

et al. 2021

Preprint

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We give a detailed treatment of electromagnetic signals generated by gravitational waves (GWs) in resonant cavity experiments. Our investigation corrects and builds upon previous studies by carefully accounting for the gauge dependence of relevant quantities. We work in a preferred frame for the laboratory, the proper detector frame, and show how to resum short-wavelength effects to provide analytic results that are exact for GWs of arbitrary wavelength. This formalism allows us to firmly establish that, contrary to previous claims, cavity experiments designed for the detection of axion dark matter only need to reanalyze existing data to search for high-frequency GWs with strains as small as h ∼ 10 −22 − 10 −21 . We also argue that directional detection is possible in principle using readout of multiple cavity modes. Further improvements in sensitivity are expected with cutting-edge advances in superconducting cavity technology.

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“…The most widely developed technique to form the A15 Nb 3 Sn phase on Nb is Sn vapor diffusion in bulk Nb, initially developed by Siemens in the 90s and rekindled in 2010s by Cornell, Fermi Lab and Jefferson Lab. Improvements in understanding the materials science and refinement of the coating process have led to resolving the precipitous Q-slope, increasing the maximum attainable accelerating gradient by a factor of 5 with Q 0 > 10 10 at 4.2 K [39][40][41][42]. However, Nb 3 Sn cavity performance has yet to reach its full potential.…”

Section: Nb 3 Sn and Other A15 Compoundsmentioning

confidence: 99%

Next-Generation Superconducting RF Technology based on Advanced Thin Film Technologies and Innovative Materials for Accelerator Enhanced Performance and Energy Reach

Valente-Feliciano,

Antoine,

Anlage

et al. 2022

Preprint

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Superconducting radio frequency (SRF) systems, essentially based on bulk niobium (Nb), are the workhorse of most particle accelerators and achieve high levels of performance and reliability. Today's exceptional performance of bulk Nb SRF cavities is the fruit of more than five decades of intensive research, essentially aimed at optimizing the material for thermal stabilization of defects, and significant funding efforts. Last incremental advances with several novel surface treatments are allowing Nb cavities to exceed previous record Q factors and avoiding degradation with increasing gradients. These include nitrogen infusion and doping, oxygen alloying with a two-step baking process. The next generation of particle accelerators will require operational parameters beyond the state-of-the-art Nb capabilities. Superconducting RF has then to rely on superior materials and advanced surfaces beyond bulk Nb for a leap in performance and efficiency. The SRF thin film development strategy aims at transforming the current SRF technology into a technology using highly functional materials, where all the necessary functions are addressed. The community is deploying efforts in three research thrusts to develop the next-generation thin-film based cavities. The first line of developments aims at investigating Nb/Cu coated cavities that perform as good as or better than bulk niobium at reduced cost and with better thermal stability. Recent results with greatly improved accelerating field and dramatically reduced Q-slope show the potential of this technology for many applications. In particular high current storage ring colliders such as FCC, EIC and CEPC, where the frequency is typically lower and the gradients are modest, could benefit greatly from the cost savings and operational advantages of this technology. The second research thrust is to develop cavities coated with materials that can operate at higher temperatures or sustain higher fields. Proof-of-principle has been established for the merit of Nb 3 Sn for SRF applications. Research is now needed to further exploit the material and reach its full potential with novel deposition techniques. The third line of research is to push SRF performance beyond the capabilities of the superconductors alone with multi-layer coatings. In parallel, developments are needed to provide quality substrates, innovative cooling schemes and cryomodule design tailored to SRF thin film cavities.Recent results in these three research thrusts suggest that SRF thin film technologies are at the eve of a technological revolution. However, in order for them to mature, active community support and sustained funding are needed and should address fundamental developments supporting material deposition techniques, surface and RF research, and technical challenges associated with scaling, automation and industrialization. With dedicated and sustained investment in SRF thin film R&D, next-generation thin-film based cavities will become a reality with high performance and efficiency, facilitating energy su...

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Advances in Nb₃Sn superconducting radiofrequency cavities towards first practical accelerator applications

Cited by 63 publications

References 42 publications

Key directions for research and development of superconducting radio frequency cavities

Key directions for research and development of superconducting radio frequency cavities

Detecting High-Frequency Gravitational Waves with Microwave Cavities

Next-Generation Superconducting RF Technology based on Advanced Thin Film Technologies and Innovative Materials for Accelerator Enhanced Performance and Energy Reach

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Advances in Nb3Sn superconducting radiofrequency cavities towards first practical accelerator applications

Cited by 63 publications

References 42 publications

Key directions for research and development of superconducting radio frequency cavities

Key directions for research and development of superconducting radio frequency cavities

Detecting High-Frequency Gravitational Waves with Microwave Cavities

Next-Generation Superconducting RF Technology based on Advanced Thin Film Technologies and Innovative Materials for Accelerator Enhanced Performance and Energy Reach

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Advances in Nb₃Sn superconducting radiofrequency cavities towards first practical accelerator applications