[1] Lund H, Munster E. Management of surplus electricity-production from a fluctuating renewable-energy source. Applied Energy, 2003, 76(1–3): 65–74

[2] Lv W, Zhang R, Gao P, Lei L. Studies on the faradaic efficiency for electrochemical reduction of carbon dioxide to formate on tin electrode. Journal of Power Sources, 2014, 253: 276–281

[3] Zhou F, Azofra L M, Ali M, Kar M, Simonov A N, McDonnell- Worth C, Sun C, Zhang X, MacFarlane D R. Electro-synthesis of ammonia from nitrogen at ambient temperature and pressure in ionic liquids. Energy & Environmental Science, 2017, 10(12): 2516–2520

[4] Thomas H. The Alchemy of Air: A Jewish Genius, A Doomed Tycoon, and The Scientific Discovery That Fed The World But Fueled The Rise Of Hitler. 1st ed. New York: Harmony Books, 2008

[5] Schrock R R. Reduction of dinitrogen. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103 Fig. 4 Scheme of the ideal setup of plasma-assisted nitrogen fixation and simplified process. MFC stands for mass flow controller; DBD stands for dielectric barrier discharge setup; FTIR stands for Fourier transform infrared spectrometer Yi HE et al. Non-thermal plasma fixing of nitrogen into nitrate: solution for renewable electricity storage? 95 (46): 17087

[6] Erisman J W, Sutton M A, Galloway J, Klimont Z, Winiwarter W. How acentury of ammonia synthesis changed the world. Nature Geoscience, 2008, 1(10): 636–639

[7] Cherkasov N, Ibhadon A O, Fitzpatrick P. A review of the existing and alternative methods for greener nitrogen fixation. Chemical Engineering and Processing, 2015, 90: 24–33

[8] Kipouros G J, Sadoway D R. Toward new technologies for the production of lithium. JOM, 1998, 50(5): 24–26

[9] Appl M. The Haber–Bosch heritage: the ammonia production technology. In: Proceedings of 50th Anniversary IFA Technical Conference, 1997, 25

[10] Legasov V A, Rusanov V D, Fridman A A. Non-equilibrium plasma-chemical processes in heterogeneous media. Plasma Chemistry, 1978, 5: 222–241

[11] Rusanov V D, Fridman A A, Sholin G V. The physics of a chemically active plasma with nonequilibrium vibrational excitation of molecules. Soviet Physics-Uspekhi, 1981, 24(6): 447–474

[12] Mccollum E D, Daniels F. Experiments on the arc process for nitrogen fixation. Industrial & Engineering Chemistry, 1923, 15(11): 1173–1175

[13] Partridge W S, Parlin R B, Zwolinski B J. Fixation of nitrogen in a crossed discharge. Industrial & Engineering Chemistry, 1954, 46(7): 1468–1471

[14] Rahman M, Cooray V. NOx generation in laser-produced plasma in air as a function of dissipated energy. Optics & Laser Technology, 2003, 35(7): 543–546

[15] Namihira T, Katsuki S, Hackam R, Akiyama H, Okamoto K. Production of nitric oxide using a pulsed arc discharge. IEEE Transactions on Plasma Science, 2002, 30(5): 1993–1998

[16] Wang W, Patil B, Heijkers S, Hessel V, Bogaerts A. Nitrogen fixation by gliding arc plasma: better insight by chemical kinetics modelling. ChemSusChem, 2017, 10(10): 2145–2157

[17] Patil B. Plasma (catalyst)-assisted nitrogen fixation: reactor development for nitric oxide and ammonia. Eindhoven: Technische Universiteit Eindhoven, 2017, 93–125

[18] Holland P L. Metal–dioxygen and metal–dinitrogen complexes: where are the electrons? Dalton Transactions (Cambridge, England), 2010, 39(23): 5415–5425