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Cited by:

1. V. Ivrii, Eigenvalue asymptotics for Schrödinger and Dirac operators with constant magnetic field and with electric potential decreasing at infinity, In: Journées “Equations aux dérivées partielles”, St.Jean-de-Monts, (1991), SMF, Exposé X.

2. V. Ivrii, Microlocal analysis and precise spectral asymptotics, Springer, Berlin-New York, Heidelberg, 1998.

3. G. Rozenblum, M. Solomyak, On the number of negative eigenvalues for the two-dimensional magnetic Schrödinger operator, In: Differential Operators and Spectral Theory: M. Sh. Birman’s 70th Anniversary Collection, AMS Translations 2 189 (1999), 205-217.

4. V. Ivrii, Sharp spectral asymptotics for the magnetic Schrödinger operator with irregular potential, Russian J. Math. Phys. 11 (2004), 415-428.

5. S. Shirai, Strong-electric-field eigenvalue asymptotics for the Iwatsuka model, J. Math. Phys. 46 (2005), 052112 (22 pages).

6. A. T. Duong, Théories spectrale et de résonances pour l’opérateur de Schrödinger avec champ magnétique, Thèse de Doctorat, Université de Paris 13, 2013.

7. M. Dimassi, A. T. Duong, Trace asymptotics formula for the Schrödinger operators with constant magnetic fields, J. Math. Anal. Appl. 416 (2014), 427-448.

8.  D. S. Delion, S. A. Ghinescu, Geiger-Nuttall law for nuclei in strong electromagnetic fields, Phys. Rev. Let. 119 (2017), 202501, 5 pp.

9. M. Dimassi, A. T. Duong, Semi-classical asymptotics for the Schrödinger operators with constant magnetic fields, In: PDE's, dispersion, scattering theory and control theory, 45-58, Sémin. Congr., 30, Soc. Math. France, Paris, 2017. 

10. D. S. Delion, S. A. Ghinescu,  Alpha-clustering in strong electromagnetic  fields, AIP Conference Proceedings 2076 (2019), 020002, 10pp. 

11. V. Ivrii, Microlocal Analysis, Sharp Spectral Asymptotics and Applications. IV. Magnetic Schrödinger operator 2, Springer, Cham, 2019. 

12. S. A. Ghinescu, D. S. Delion, Coupled-channels analysis of the decay in strong electromagnetic fields, Phys. Rev. C 101 (2020), 044304.

13. R.L. Frank, H. Kovařík, Lieb–Thirring Inequality for the 2D Pauli Operator, Commun. Math. Phys. 406 (2025) no. 2, article 23. https://doi.org/10.1007/s00220-024-05177-2 .

14. M. Baur, H. Kovarik, Cwikel-Lieb-Rozenblum type estimates for the Pauli and magnetic Schrödinger operator in dimension two, Preprint arXiv:2505.00428, 2025.