Simulating MADMAX in 3D: Requirements for Dielectric Axion Haloscopes

MADMAX collaboration,; Knirck, S.; Schütte-Engel, J.; Beurthey, S.; Breitmoser, D.; Caldwell, A.; Diaconu, C.; Diehl, J.; Egge, J.; Esposito, M.; Gardikiotis, A.; Garutti, E.; Heyminck, S.; Hubaut, F.; Jochum, J.; Karst, P.; Kramer, M.; Krieger, C.; Labat, D.; Lee, C.; Li, X.; Lindner, A.; Majorovits, B.; Martens, S.; Matysek, M.; Öz, E.; Planat, L.; Pralavorio, P.; Raffelt, G.; Ranadive, A.; Redondo, J.; Reimann, O.; Ringwald, A.; Roch, N.; Schaffran, J.; Schmidt, A.; Shtembari, L.; Steffen, F.; Strandhagen, C.; Strom, D.; Usherov, I.; Wieching, G.

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Simulating MADMAX in 3D: Requirements for Dielectric Axion Haloscopes

MADMAX collaboration, Knirck, S., Schütte-Engel, J., Beurthey, S., Breitmoser, D., Caldwell, A., et al. (2021). Simulating MADMAX in 3D: Requirements for Dielectric Axion Haloscopes. Journal of Cosmology and Astroparticle Physics, 10, 034. Retrieved from https://publications.mppmu.mpg.de/?action=search&mpi=MPP-2021-61.

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Datensatz-Permalink: https://hdl.handle.net/21.11116/0000-000A-1ACA-6 Versions-Permalink: https://hdl.handle.net/21.11116/0000-000A-1ACB-5

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MADMAX collaboration¹, Autor
Knirck, S.¹, Autor
Schütte-Engel, J.¹, Autor
Beurthey, S.¹, Autor
Breitmoser, D.¹, Autor
Caldwell, A.¹, Autor
Diaconu, C.¹, Autor
Diehl, J.¹, Autor
Egge, J.¹, Autor
Esposito, M.¹, Autor
Gardikiotis, A.¹, Autor
Garutti, E.¹, Autor
Heyminck, S.¹, Autor
Hubaut, F.¹, Autor
Jochum, J.¹, Autor
Karst, P.¹, Autor
Kramer, M.¹, Autor
Krieger, C.¹, Autor
Labat, D.¹, Autor
Lee, C.¹, Autor
Li, X.¹, AutorLindner, A.¹, AutorMajorovits, B.¹, AutorMartens, S.¹, AutorMatysek, M.¹, AutorÖz, E.¹, AutorPlanat, L.¹, AutorPralavorio, P.¹, AutorRaffelt, G.¹, AutorRanadive, A.¹, AutorRedondo, J.¹, AutorReimann, O.¹, AutorRingwald, A.¹, AutorRoch, N.¹, AutorSchaffran, J.¹, AutorSchmidt, A.¹, AutorShtembari, L.¹, AutorSteffen, F.¹, AutorStrandhagen, C.¹, AutorStrom, D.¹, AutorUsherov, I.¹, AutorWieching, G.¹, Autor mehr..

Affiliations:
1Max Planck Institute for Physics, Max Planck Society and Cooperation Partners, ou_2253650

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Schlagwörter: MADMAX

Zusammenfassung: We present 3D calculations for dielectric haloscopes such as the currently envisioned MADMAX experiment. For ideal systems with perfectly flat, parallel and isotropic dielectric disks of finite diameter, we find that a geometrical form factor reduces the emitted power by up to $30\,\%$ compared to earlier 1D calculations. We derive the emitted beam shape, which is important for antenna design. We show that realistic dark matter axion velocities of $10^{-3} c$ and inhomogeneities of the external magnetic field at the scale of $10\,\%$ have negligible impact on the sensitivity of MADMAX. We investigate design requirements for which the emitted power changes by less than $20\,\%$ for a benchmark boost factor with a bandwidth of $50\,{\rm MHz}$ at $22\,{\rm GHz}$, corresponding to an axion mass of $90\,\mu{\rm eV}$. We find that the maximum allowed disk tilt is $100\,\mu{\rm m}$ divided by the disk diameter, the required disk planarity is $20\,\mu{\rm m}$ (min-to-max) or better, and the maximum allowed surface roughness is $100\,\mu{\rm m}$ (min-to-max). We show how using tiled dielectric disks glued together from multiple smaller patches can affect the beam shape and antenna coupling.