D. Public datasets, Zenodo publications, etc.

46. 

Brandenburg, A., & Protiti, N. N.: 2023, Datasets for ``Electromagnetic conversion into kinetic and thermal energies'' v2023.08.01. Zenodo, DOI:10.5281/zenodo.xxxxxxx (HTML, DOI)

45. 

Brandenburg, A., Clarke, E., Kahniashvili, T., Long, A. J., & Sun, G.: 2023, Datasets for ``Relic gravitational waves from the chiral plasma instability in the standard cosmological model'' v2023.07.17. Zenodo, DOI:10.5281/zenodo.8157463 (HTML, DOI)

44. 

Brandenburg, A., Sharma, R., & Vachaspati, T.: 2023, Datasets for ``Inverse cascading for initial MHD turbulence spectra between Saffman and Batchelor'' v2023.07.09. Zenodo, DOI:10.5281/zenodo.8128611 (HTML, DOI)

43. 

Brandenburg, A., Kamada, K., Mukaida, K., Schmitz, K., & Schober, J.: 2023, Datasets for ``Chiral magnetohydrodynamics with zero total chirality'' v2023.03.10. Zenodo, DOI:10.5281/zenodo.xxxxxxx (HTML)

42. 

Sarin, N., Brandenburg, A., & Haskell, B.: 2023, Supplemental Material to ``Confronting the neutron star population with inverse cascades'' v2023.06.27. Zenodo, DOI:10.5281/zenodo.8088084 (HTML, DOI)

41. 

Mizerski, K. A., Yokoi, N., & Brandenburg, A.: 2023, Datasets for ``Cross-helicity effect on $\alpha$-type dynamo in non-equilibrium turbulence'' v2023.02.28. Zenodo, DOI:10.5281/zenodo.7683615 (HTML, DOI)

40. 

Brandenburg, A., Kamada, K., & Schober, J.: 2023, Datasets for ``Decay law of magnetic turbulence with helicity balanced by chiral fermions'' v2023.02.01. Zenodo, DOI:10.5281/zenodo.7499431 (HTML)

39. 

Brandenburg, A.: 2023, Datasets for ``Quadratic growth during the COVID-19 pandemic: merging hotspots and reinfections'' v2023.01.02. Zenodo, DOI:10.5281/zenodo.7499431 (HTML, DOI)

38. 

Brandenburg, A.: 2022, Datasets for ``Hosking integral in nonhelical Hall cascade'' v2022.11.24. Zenodo, DOI:10.5281/zenodo.7357799 (HTML, DOI)

37. 

He, Y., Roper Pol, A., & Brandenburg, A.: 2022, Datasets of ``Modified propagation of gravitational waves from the early radiation era'' v2022.11.16. Zenodo, DOI:10.5281/zenodo.7327770 (HTML, DOI)

36. 

Brandenburg, A., Rogachevskii, I., & Schober, J.: 2022, Datasets for ``Dissipative magnetic structures and scales in small-scale dynamos'' v2022.9.18. Zenodo, DOI:10.5281/zenodo.7090887 (HTML, DOI)

35. 

Carenza, P., Sharma, R., Marsh, M. C. D., Brandenburg, A., Müller, E.: 2022, Datasets for ``Magnetohydrodynamics predicts heavy-tailed distributions of axion-photon conversion'' v2022.8.8. Zenodo, DOI:10.5281/zenodo.6974228 (HTML, DOI)

34. 

Brandenburg, A., Zhou, H., & Sharma, R.: 2022, Datasets for ``Batchelor, Saffman, and Kazantsev spectra in galactic small-scale dynamos'' v2022.07.19. Zenodo, DOI:10.5281/zenodo.7281479 (HTML, DOI)

33. 

Zhou, H., Sharma, R., & Brandenburg, A.: 2022, Datasets for ``Scaling of the Hosking integral in decaying magnetically-dominated turbulence'' v2022.06.14. Zenodo, DOI:10.5281/zenodo.7112885 (HTML, DOI)

32. 

Sharma, R., & Brandenburg, A.: 2022, Supplemental Material and Datasets for ``Low frequency tail of gravitational wave spectra from hydromagnetic turbulence'' v2022.08.22. Zenodo, DOI:10.5281/zenodo.7014823 (HTML, DOI)

31. 

Käpylä, M. J., Rheinhardt, M., & Brandenburg, A.: 2022, Datasets for ``Fully compressible test-field method and its application to shear dynamos'' v2022.03.24. Zenodo, DOI:10.5281/zenodo.6383190 (HTML, DOI)

30. 

Brandenburg, A., & Ntormousi, E.: 2021, Datasets for ``Dynamo effect in unstirred self-gravitating turbulence'' v2021.12.06. Zenodo, DOI:10.5281/zenodo.5760126 (HTML, DOI)

29. 

Kahniashvili, T., Clarke, E., Stepp, J., & Brandenburg, A.: 2021, Datasets for ``Big bang nucleosynthesis limits and relic gravitational waves detection prospects'' v2021.11.18. Zenodo, DOI:10.5281/zenodo.5709176 (HTML, DOI)

28. 

Roper Pol, A., Mandal, S., Brandenburg, A., & Kahniashvili, T.: 2021, Datasets for ``Polarization of gravitational waves from helical MHD turbulent sources'' v2021.09.24. Zenodo, DOI:10.5281/zenodo.5525504 (HTML, DOI)

27. 

He, Y., Roper Pol, A., & Brandenburg, A.: 2021, Datasets for ``Leading-order nonlinear gravitational waves from reheating magnetogeneses'' v2021.09.23. Zenodo, DOI:10.5281/zenodo.5524454(HTML, DOI)

26. 

Brandenburg, A., He, Y., & Sharma, R.: 2021, Datasets for ``Simulations of helical inflationary magnetogenesis and gravitational waves'' v2021.07.26. Zenodo, DOI:10.5281/zenodo.5137202 (HTML, DOI)

25. 

Brandenburg, A., & Sharma, R.: 2021, Datasets for ``Simulating relic gravitational waves from inflationary magnetogenesis'' v2021.06.04. Zenodo, DOI:10.5281/zenodo.4900075 (HTML, DOI)

24. 

Li, X.-Y., Mehlig, B., Svensson, G., Brandenburg, A., & Haugen, N. E. L.: 2021, Datasets for ``Collision fluctuations of lucky droplets with superdroplets'' v2021.05.07. Zenodo, DOI:10.5281/zenodo.4742786 (HTML, DOI)

23. 

Haugen, N. E. L., Brandenburg, A., Sandin, C., & Mattsson, L.: 2021, Datasets for ``Spectral characterisation of inertial particle clustering in turbulence'' v2021.05.02. Zenodo, DOI:10.5281/zenodo.4733175 (HTML, DOI)

22. 

He, Y., Brandenburg, A., & Sinha, A.: 2021, Datasets for ``Spectrum of turbulence-sourced gravitational waves as a constraint on graviton mass'' v2021.04.06. Zenodo, DOI:10.5281/zenodo.4666074 (HTML, DOI)

21. 

Brandenburg, A., Clarke, E., He, Y., & Kahniashvili, T.: 2021, Datasets for ``Can we observe the QCD phase transition-generated gravitational waves through pulsar timing arrays?'' v2021.02.24. Zenodo, DOI:10.5281/zenodo.4560423 (HTML, DOI)

20. 

Brandenburg, A., He, Y., Kahniashvili, T., Rheinhardt, M., & Schober, J.: 2021, Datasets for ``Gravitational waves from the chiral magnetic effect,'' v2021.01.18. Zenodo, DOI:10.5281/zenodo.4448211 (HTML, DOI)

19. 

Haugen, N. E. L., & Brandenburg, A.: 2020, Datasets for ``Hydrodynamic and hydromagnetic energy spectra from large eddy simulations,'' v2020.12.08. DOI:10.5281/zenodo.4311391 (HTML, DOI)

18. 

Jakab, P., & Brandenburg, A.: 2020, Datasets for ``The effect of a dynamo-generated field on the Parker wind,'' v2020.11.22. DOI:10.5281/zenodo.4284439 (HTML, DOI)

17. 

Kahniashvili, T., Brandenburg, A., Gogoberidze, G., Mandal, S., & Roper Pol, A.: 2020, Datasets for ``Circular polarization of gravitational waves from early-universe helical turbulence,'' v2020.11.07. DOI:10.5281/zenodo.4256906 (HTML, DOI)

16. 

Brandenburg, A., & Das, U.: 2020, Datasets for ``Turbulent radiative diffusion and turbulent Newtonian cooling,'' v2020.10.13b. DOI:10.5281/zenodo.4086046 (HTML, DOI)

15. 

Merski, M.: 2020, Datasets for ``A simple model to predict future SARS-CoV-2 infections on a national level,'' v2020.10.11. DOI:10.5281/zenodo.4256906 (HTML, DOI)

14. 

Brandenburg, A.: 2020, Datasets for ``Piecewise quadratic growth during the 2019 novel coronavirus epidemic,'' v2020.09.07. DOI:10.5281/zenodo.4016941 (HTML, DOI)

13. 

Brandenburg, A.: 2020, Datasets for ``Hall cascade with fractional magnetic helicity in neutron star crusts,'' v2020.07.20. DOI:10.5281/zenodo.3951873 (HTML, HTML, DOI)

12. 

Brandenburg, A., & Furuya, R. S.: 2020, Datasets for ``Application of a helicity proxy to edge-on galaxies,'' v2020.06.17. DOI:10.5281/zenodo.3897954 (HTML, HTML, DOI)

11. 

Prabhu, A., Brandenburg, A., Käpylä, M. J., & Lagg, A.: 2020, Datasets for ``Helicity proxies from linear polarisation of solar active regions,'' v2020.06.10. DOI:10.5281/zenodo.3888575 (HTML, DOI)

10. 

Pusztai, I., Juno, J., Brandenburg, A., TenBarge, J. M., Hakim, A., Francisquez, M., & Sundström, A.: 2020, Datasets for ``Dynamo in weakly collisional non-magnetized plasmas impeded by Landau damping of magnetic fields,'' v1. DOI:10.5281/zenodo.3886562 (HTML, HTML, DOI)

9. 

Brandenburg, A., & Brüggen, M.: 2020, Datasets for ``Hemispheric handedness in the Galactic synchrotron polarization foreground,'' v2020.05.24. DOI:10.5281/zenodo.3841900 (HTML, HTML, DOI)

8. 

Roper Pol, A., Mandal, S., Brandenburg, A., Kahniashvili, T., & Kosowsky, A.: 2020, Datasets for ``Numerical Simulations of Gravitational Waves from Early-Universe Turbulence''' v2020.02.28. DOI:10.5281/zenodo.3692072 (HTML, DOI)

7. 

Brandenburg, A., & Scannapieco, E.: 2019, Datasets for ``Magnetic helicity dissipation and production in an ideal MHD code,'' v2019.11.11. DOI:10.5281/zenodo.3534739 (HTML, DOI)

6. 

Brandenburg, A., & Chen, L.: 2019, Datasets for ``The nature of mean-field generation in three classes of optimal dynamos,'' v2019.11.02. DOI:10.5281/zenodo.3526056 (HTML, DOI)

5. 

Brandenburg, A.: 2019, Scientific usage of the Pencil Code, v2019.10.01. DOI:10.5281/zenodo.3466444 (ADS, HTML, HTML, DOI)

4. 

Brandenburg, A., Kahniashvili, T., Mandal, S., Roper Pol, A., Tevzadze, A. G., & Vachaspati, T.: 2019, Datasets for ``Dynamo effect in decaying helical turbulence,'' v2019.07.21. DOI:10.5281/zenodo.3345134 (HTML, HTML, DOI)

3. 

Gosain, S., & Brandenburg, A.: 2019, Datasets for ``Spectral magnetic helicity of solar active regions between 2006 and 2017,'' v2019.07.16. DOI:10.5281/zenodo.3338302 (HTML, HTML, DOI)

2. 

Li, X.-Y., Svensson, G., Brandenburg, A., & Haugen, N. E. L.: 2019, Datasets for ``Cloud droplet growth due to supersaturation fluctuations in stratiform clouds,'' v2019.01.11. DOI:10.5281/zenodo.2538027 (HTML, HTML, DOI)

1. 

Brandenburg, A., on behalf of the Pencil Code Collaboration: 2018, Pencil Code v2018.12.16. DOI:10.5281/zenodo.2315093 and 3961647(ADS, HTML, DOI)