posted on 2021-07-23, 20:29authored byBernhard
M. H. Weninger, Michel A. Thijs, Jeroen A. C. Nijman, Lambert van Eijck, Fokko M. Mulder
Iron is a promising,
earth-abundant material for future energy
applications. In this study, we use a neutron diffractometer to investigate
the properties of an iron electrode in an alkaline environment. As
neutrons penetrate deeply into materials, neutron scattering gives
us a unique insight into what is happening inside the electrode. We
made our measurements while
the electrode was charging or discharging. Our key questions are:
Which phases occur for the first and second discharge plateaus? And
why are iron electrodes less responsive at higher discharge rates?
We conclude that metallic iron and iron hydroxide form the redox pair
for the first discharge plateau. For the second discharge plateau,
we found a phase similar to feroxyhyte but with symmetrical and equally
spaced arrangement of hydrogen atoms. The data suggest that no other
iron oxide or iron (oxy)hydroxide formed. Remarkable findings include
the following: (1) substantial amounts of iron hydroxide are always
present inside the electrode. (2) Passivation is mostly caused by
iron hydroxide that is unable to recharge. (3) Iron fractions change
as expected, while iron hydroxide fractions are delayed, resulting
in substantial amounts of amorphous, undetectable iron phases. About
40% of the participating iron of the first plateau and about 55% of
the participating iron for the second plateau are undetectable. (4)
Massive and unexpected precipitation of iron hydroxide occurs in the
transition from discharging to charging. (2), (3), and (4) together
cause accumulation of iron hydroxide inside the electrode.