133.Black, J.H., Chemistry and cosmology. Faraday Discussions, 2006. 133: p. 27-32; discussion 83-102, 449-52.
134.Buxton, G.V., et al., Critical view of rate constants for reactions of hydrated electrons, hydrogen atoms and hydroxyl radicals (•OH/•OH–) in aqueous solution. J Phys Chem Ref Data, 1988. 17: p. 513-886.
135.Choi, W.K., Investigations of Quantitative Reducibility Determination and Reducibility Variations of Neutral Hydrogen-Dissolved Water by Electrochemical Analysis. Int. J. Electrochem. Sci, 2014. 9: p. 7266-7276.
136.Donald, W.A., et al., Directly relating gas-phase cluster measurements to solution-phase hydrolysis, the absolute standard hydrogen electrode potential, and the absolute proton solvation energy. Chemistry, 2009. 15(24): p. 5926-34.
137.Ehrenfreund, P., et al., Astrophysical and astrochemical insights into the origin of life. Reports on Progress in Physics, 2002. 65(10): p. 1427-1487.
138.Hamasaki, T., et al., Kinetic analysis of superoxide anion radical-scavenging and hydroxyl radical-scavenging activities of platinum nanoparticles. Langmuir, 2008. 24(14): p. 7354-64.
139.Huber, C. and G. Wachtershauser, alpha-Hydroxy and alpha-amino acids under possible Hadean, volcanic origin-of-life conditions. Science, 2006. 314(5799): p. 630-2.
140.Jain, I.P., Hydrogen the fuel for 21st century. International Journal of Hydrogen Energy, 2009. 34(17): p. 7368-7378.
141.Kikuchi, K., et al., Characteristics of hydrogen nanobubbles in solutions obtained with water electrolysis. Journal of Electroanalytical Chemistry, 2007. 600(2): p. 303-310.
142.Kikuchi, K., et al., Hydrogen particles and supersaturation in alkaline water from an Alkali-Ion-Water electrolyzer.Journal of Electroanalytical Chemistry, 2001. 506(1): p. 22-27.
143.Kikuchi, K., et al., Hydrogen concentration in water from an Alkali-Ion-Water electrolyzer having a platinum-electroplated titanium electrode. Journal of Applied Electrochemistry, 2001. 31(12): p. 1301-1306.
144.Klunder, K., et al., A Study of Dissolved Gas Dynamics in Mixed Stream Electrolyzed Water. Electrochemistry, 2012. 80(8): p. 574-577.
145.Kuhlmann, J., et al., Fast escape of hydrogen from gas cavities around corroding magnesium implants. Acta Biomater, 2012.
146.Liu, W., X. Sun, and S. Ohta, Hydrogen Element and Hydrogen Gas. Hydrogen Molecular Biology and Medicine. 2015: Springer Netherlands.
147.Ramachandran, R. and R.K. Menon, An overview of industrial uses of hydrogen. International Journal of Hydrogen Energy, 1998. 23(7): p. 593-598.
148.Renault, J.P., R. Vuilleumier, and S. Pommeret, Hydrated electron production by reaction of hydrogen atoms with hydroxide ions: A first-principles molecular dynamics study. Journal of Physical Chemistry A, 2008. 112(30): p. 7027-7034.
149.Sabo, D., et al., Molecular studies of the structural properties of hydrogen gas in bulk water. Molecular Simulation, 2006. 32(3-4): p. 269-278.
150.Seo, T., R. Kurokawa, and B. Sato, A convenient method for determining the concentration of hydrogen in water: use of methylene blue with colloidal platinum. Medical Gas Research, 2012. 2: p. 1.
151.Takenouchi, T., U. Sato, and Y. Nishio, Behavior of Hydrogen Nanobubbles Generated in Alkaline Electrolyzed Water. Electrochemistry, 2009. 77(7): p. 521-523.
152.Tanaka, Y., et al., Dissolution of hydrogen and the ratio of the dissolved hydrogen content to the produced hydrogen in electrolyzed water using SPE water electrolyzer. Electrochimica Acta, 2003. 48(27): p. 4013-4019.
153.Zeng, K. and D.K. Zhang, Recent progress in alkaline water electrolysis for hydrogen production and applications. Progress in Energy and Combustion Science, 2010. 36(3): p. 307-326.
154.Zheng, Y.F., X.N. Gu, and F. Witte., Biodegradable metals. Materials Science and Engineering: R: Reports, 2014.77: p. 1-34.