[1] P.Zeeman. XXXII. On the influence of magnetism on the nature of the light emitted by a sub-stance. London, Edinburgh Dublin Philos. Mag. J. Sci., 43, 226-239(1897).
[2] W. L.Virgo. Simultaneous Stark and Zeeman effects in atoms with hyperfine structure. Am. J. Phys., 81, 936-942(2013).
[3] L.Eaves, C.Uihlein. High-magnetic-field Zeeman spectroscopy of the 0.84-eV Cr-related emission and absorption line in GaAs(Cr): Experiment and theory. Phys. Rev. B, 26, 4473-4484(1982).
[4] A.Iwamae, M.Goto, K.Fujii, T.Shikama, S.Morita, K.Mizushiri, M.Hasuo. A simultaneous measurement of polarization-resolved spectra of neutral helium 23P–33D, 21P–31D and 23P–33S emissions from the periphery of a Large Helical Device plasma. Plasma Phys. Controlled Fusion, 53, 105012-105024(2011).
[5] P.Mertens, C. C.Chu, B.Unterberg, S.Brezinsek, J. D.Hey. Oxygen ion impurity in the TEXTOR tokamak boundary plasma observed and analysed by Zeeman spectroscopy. J. Phys. B: At., Mol. Opt. Phys., 35, 1525-1553(2002).
[6] D.Deming, G.Wiedemann, D. E.Jennings, R. J.Boyle. Solar magnetic field studies using the 12 micron emission lines. I. Quiet-sun time series and sunspot slices: Erratum. Astrophys. J., 338, 1193(1989).
[7] H. W.Babcock. Zeeman effect in stellar spectra. Astrophys. J., 105, 105(1947).
[8] S. K.Solanki, A.Reiners, R. I.Anderson. On detectability of Zeeman broadening in optical spectra of F- and G-dwarfs. Astron. Astrophys., 522, A81(2010).
[9] J. D.Bailey. Measuring the surface magnetic fields of magnetic stars with unresolved Zeeman splitting. Astron. Astrophys., 568, A38(2014).
[10] J.Ferreira. Magnetically-driven jets from Keplerian accretion discs. Astron. Astrophys., 319, 340-359(1997).
[11] R. A.Kopp, G. W.Pneuman. Magnetic reconnection in the corona and the loop prominence phenomenon. Sol. Phys., 50, 85-98(1976).
[12] S.Masuda, Y.Ogawara, H.Hara, S.Tsuneta, T.Kosugi. A loop-top hard X-ray source in a compact solar flare as evidence for magnetic reconnection. Nature, 371, 495-497(1994).
[13] E. A.McLean, C. K.Manka, J. A.Stamper, H. R.Griem, B. H.Ripin, D. W.Droemer. Observation of magnetic fields in laser-produced plasma using the Zeeman effect. Phys. Fluids, 27, 1327-1335(1984).
[14] J. P.Dinguirard, C.Arnas, M.El Tamer, J. C.Kieffer, A.Gomes, J.Briand, Y.Quemener, M.Armengaud, L.Berge. Measurements of magnetic fields using the Zeeman effect in laser-produced plasmas. Phys. Fluids, 30, 2893-2897(1987).
[15] Y.Arikawa, T.Shiroto, Y.Sentoku, S.Tokita, A.Syuhada, H.Nagatomo, T.Ozaki, J. J.Santos, Y.Nakata, H.Nishimura, M.Nakai, H.Sawada, A.Sunahara, K.Yamanoi, M.Bailly-Grandvaux, R.Kodama, Y.Iwasa, H.Sakagami, K. F. F.Law, N.Iwata, K.Mima, S.Kojima, H.Morita, T.Norimatsu, H.Kishimoto, S.Fujioka, H.Shiraga, J.Kawanaka, S.Lee, Y.Abe, A.Yao, M.Hata, A.Yogo, T.Johzaki, H.Azechi, S.Sakata, N.Miyanaga, A.Morace, K.Matsuo. Magnetized fast isochoric laser heating for efficient creation of ultra-high-energy-density states. Nat. Commun., 9, 3937(2018).
[17] C.Yamanaka, S.Nakai, K.Mima, K.Sawai, F.Miki, H.Daido, M.Fujita, Y.Kitagawa, H.Fujita. Generation of a strong magnetic field by an intense CO2 laser pulse. Phys. Rev. Lett., 56, 846-849(1986).
[18] Y.Hironaka, N.Yamamoto, K.Shigemori, T.Johzaki, H.Shiraga, Z.Zhang, S.Fujioka, A.Sunahara, K.Ishihara, H.Azechi, H.Nakashima, H.Nishimura, T.Watanabe. Kilotesla magnetic field due to a capacitor-coil target driven by high power laser. Sci. Rep., 3, 1170(2013).
[19] Z.Zhang, N.Xie, F. B.Xue, F. Q.Zhang, B.Han, J. Y.Zhong, Y. T.Li, J.Zhang, W. M.Wang, Y. Q.Gu, C.Liu, L.Yang, J. Q.Zhu, S. K.He, X. X.Pei, G. Q.Liao, W. W.Wang, H. G.Wei, W.Hong, B. H.Zhang, Z. Q.Zhao, F.Li, Y. F.Li, F.Lu, K.Zhang, K. N.Zhou, B. J.Zhu, G.Zhao, D. W.Yuan, J. R.Zhao. Strong magnetic fields generated with a simple open-ended coil irradiated by high power laser pulses. Appl. Phys. Lett., 107, 261903(2015).
[21] K.Kondo, C.Bellei, J. J.Santos, A.Morace, M.Bailly-Grandvaux, S.Kojima, Z.Zhang, K.Matsuo, Y.Arikawa, H.Azechi, S.Sakata, X.Vaisseau, S.Fujioka, K. F.Law, A.Yogo, S.Lee. Direct measurement of kilo-tesla level magnetic field generated with laser-driven capacitor-coil target by proton deflectometry. Appl. Phys. Lett., 108, 091104(2016).
[22] M.Evans, W.Fox, G.Fiksel, L.Gao, H.Ji, N.Alfonso. Ultrafast proton radiography of the magnetic fields generated by a laser-driven coil current. Phys. Plasmas, 23, 043106(2016).
[23] Z.Zhang, F.Wang, B.Han, W.Jiang, D.Yuan, N.Hua, B.Zhu, G.Liang, Y.Li, H.Wei, J.Zhong, G.Zhao, C.Wang, Z.Fang, J.Zhu, J.Zhang, B.Zhu. Generation of strong magnetic fields with a laser-driven coil. High Power Laser Sci. Eng., 6, e38(2018).
[24] Z.Zhang, Y.Zhang, Y.Li, W.Jiang, B.Zhu, J.Tan, J.Wang, C.Zhu, Y.Li, Y.He, J.Ma. Ultrafast pulsed magnetic fields generated by a femtosecond laser. Appl. Phys. Lett., 113, 072405(2018).
[25] Z.Zhang, Y.Li, Y.Li, C.Zhu, B.Zhu, J.Tan, J.Ma, Y.Zhang, J.Wang, Y.He, W.Jiang. Effects of pulse duration on magnetic fields generated with a laser-driven coil. High Energy Density Phys., 37, 100900(2020).
[26] Z.Zhang, Y.Li, Z.Zhao, J.Zhang, G.Liao, Y.Gu, S.He, L.Yang, F.Zhang, N.Xie, X.Wang, W.Hong, B.Zhu, F.Lu, K.Zhou, B.Zhang, M.Li, F.Li, W.Wang, Y.Li. Proton radiography of magnetic fields generated with an open-ended coil driven by high power laser pulses. Matter Radiat. Extremes, 1, 187-191(2016).
[27] P.Elleaume, O.Chubar, J.Chavanne. A three-dimensional magnetostatics computer code for insertion devices. J. Synchrotron Radiat., 5, 481-484(1998).
[28] E. U.Condon, G. H.Shortley. The Theory of Atomic Spectra(1935).
[29] A.Kramida, J.Reader, Yu.Ralchenko.
[30] E.Back, F.Paschen. Normale und anomale Zeemaneffekte. Ann. Phys., 344, 897-932(1912).
[31] F. F.Chen. Introduction to Plasma Physics and Controlled Fusion(2016).
[32] D. R.Welch, I. E.Golovkin, T. A.Mehlhorn, P. R.Woodruff, B. V.Oliver, R. B.Campbell, J. J.MacFarlane. Simulation of the ionization dynamics of aluminum irradiated by intense short-pulse lasers. Inertial Fusion Sciences and Applications 2003, 457-460(2004).
[33] N. V.Abrosimov, K. L.Litvinenko, E. T.Bowyer, I.Galbraith, C. R.Pidgeon, H.Engelkamp, B. N.Murdin, P. G.Murdin, H.Riemann, S. G.Pavlov, S. K.Clowes, H. W.Hübers, M. L.Pang, J.Li. Si:P as a laboratory analogue for hydrogen on high magnetic field white dwarf stars. Nat. Commun., 4, 1469(2013).
[34] J.Brinkmann, X.Fan, N.Silvestri, J.Krzesiski, G. D.Schmidt, J.Liebert, M. J.Collinge, B.Margon, D.Eisenstein, D. Q.Lamb, S. F.Anderson, H. C.Harris, J. A.Smith, P. B.Hall, A.Nitta, S. J.Kleinman, P.Szkody, D. P.Schneider, G. R.Knapp, S.Hawley, C. C.Dahn. SDSS white dwarfs with spectra showing atomic oxygen and/or carbon lines. Astrophys. J., 126, 2521(2003).